CN116788756B - Conveyer is used in flange part processing - Google Patents
Conveyer is used in flange part processing Download PDFInfo
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- CN116788756B CN116788756B CN202311091624.4A CN202311091624A CN116788756B CN 116788756 B CN116788756 B CN 116788756B CN 202311091624 A CN202311091624 A CN 202311091624A CN 116788756 B CN116788756 B CN 116788756B
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- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 claims abstract description 150
- 238000001816 cooling Methods 0.000 claims abstract description 132
- 230000005540 biological transmission Effects 0.000 claims abstract description 75
- 230000000712 assembly Effects 0.000 claims abstract description 17
- 238000000429 assembly Methods 0.000 claims abstract description 17
- 238000001514 detection method Methods 0.000 claims abstract description 11
- 238000004891 communication Methods 0.000 claims description 49
- 238000003754 machining Methods 0.000 claims description 13
- 238000005259 measurement Methods 0.000 claims description 13
- 239000000463 material Substances 0.000 claims description 12
- 238000002955 isolation Methods 0.000 claims description 2
- 230000000694 effects Effects 0.000 abstract description 3
- 238000005265 energy consumption Methods 0.000 abstract description 3
- 230000011664 signaling Effects 0.000 abstract 1
- 239000011148 porous material Substances 0.000 description 10
- 230000032258 transport Effects 0.000 description 3
- 239000000498 cooling water Substances 0.000 description 2
- 238000007599 discharging Methods 0.000 description 2
- 230000005484 gravity Effects 0.000 description 2
- 230000009286 beneficial effect Effects 0.000 description 1
- 230000008602 contraction Effects 0.000 description 1
- 238000010586 diagram Methods 0.000 description 1
- 238000011038 discontinuous diafiltration by volume reduction Methods 0.000 description 1
- 230000005611 electricity Effects 0.000 description 1
Classifications
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02P—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
- Y02P70/00—Climate change mitigation technologies in the production process for final industrial or consumer products
- Y02P70/10—Greenhouse gas [GHG] capture, material saving, heat recovery or other energy efficient measures, e.g. motor control, characterised by manufacturing processes, e.g. for rolling metal or metal working
Abstract
The application relates to a conveying device for flange part processing, which relates to the technical field of conveying and comprises a conveying belt, a guard plate, a measuring assembly, a water cooling assembly and a transmission assembly; the two guard plates are arranged on two sides of the conveyor belt respectively, and the guard plates are fixedly connected with the conveyor belt bracket; the measuring assembly is used for detecting the transportation state of the flange and outputting a detection signal, a cooling cavity is formed in the guard plate, and water is filled in the cooling cavity; the water cooling assembly and the transmission assembly are respectively provided with two water cooling assemblies and are in one-to-one correspondence with the guard plates; the transmission assembly is used for responding to the detection signal and controlling the water pressure in the cooling cavity; the water cooling assembly is used for responding to the water pressure in the cooling cavity and controlling the replacement of the water in the cooling cavity. The application has the effect of continuously cooling the conveyor belt on the premise of reducing energy consumption.
Description
Technical Field
The application relates to the technical field of flange machining, in particular to a conveying device for flange part machining.
Background
The transportation device for flange part processing is equipment for flange transportation in a factory building, and is mainly applied to a transportation link of a flange in flange part processing.
The existing conveyer for flange part processing generally adopts a conveyer belt to transport, and the conveyer belt cannot work continuously due to the fact that the temperature of the flange transported by the conveyer belt is high, so that cooling equipment is generally arranged on two sides of the existing conveyer belt and used for cooling the conveyer belt.
At present, the existing cooling equipment needs to be started continuously, so that more energy is consumed by the conveying device for flange part machining.
Disclosure of Invention
In order to continuously cool the conveyor belt on the premise of reducing energy consumption, the application provides a conveying device for flange part processing.
The application provides a conveying device for flange part processing, which adopts the following technical scheme:
a conveying device for flange part machining comprises a conveying belt, a guard plate, a measuring assembly, a transmission assembly and a water cooling assembly; the two guard plates are arranged on two sides of the conveyor belt respectively, and the guard plates are fixedly connected with the conveyor belt bracket; the measuring assembly is positioned on one side of the conveyor belt, is used for detecting the transportation state of the flange and is used for outputting detection signals; a cooling cavity is formed in the guard plate, and water is filled in the cooling cavity; the transmission assembly is positioned in the cooling cavity, two groups of transmission assemblies are arranged and correspond to the guard plates one by one, and the transmission assembly is used for responding to the detection signals output by the measurement assembly and controlling the water pressure in the cooling cavity; the water cooling assembly is located in the cooling cavity, two groups of water cooling assemblies are arranged and correspond to the guard plates one by one, and the water cooling assembly is used for responding to the water pressure in the cooling cavity and controlling the replacement of water in the cooling cavity.
Through adopting above-mentioned technical scheme, the transportation state of measurement assembly detection flange, and transport the flange to the conveyer belt, transmission assembly is according to the size of measurement assembly's detection signal control cooling intracavity water pressure, and the change of cooling intracavity water is controlled according to the size of cooling intracavity water pressure to the water-cooling assembly for cooling equipment changes inside cooling water according to the transportation state of flange, thereby makes cooling equipment not need to last to start, has reduced the work power consumption.
Optionally, the measuring assembly comprises a receiving plate and a measuring telescopic rod; the material receiving plate is obliquely arranged and is positioned above the conveyor belt, and one side of the material receiving plate is hinged with one side of the conveyor belt bracket; the measuring telescopic rod is vertically arranged and is positioned below the receiving plate; the movable end of the measuring telescopic rod is hinged with a sliding block, and the sliding block is in sliding connection with one side of the material receiving plate; the inside of measuring telescopic link stiff end is vertical to be provided with first spring, the one end of first spring with measure the expansion link's movable end fixed connection, and the other end with measure the stiff end fixed connection of telescopic link.
Through adopting above-mentioned technical scheme, the staff places the flange after processing on receiving the flitch, the flange slides to the conveyer belt along the incline direction of receiving the flitch, when the flange is placed to receiving the flitch, the gravity of flange self is extruded to receiving the flitch, measure the telescopic link, under the effect of external force, measure the expansion link's expansion end and remove to being close to the direction of measuring the telescopic link stiff end, make the inside volume of measuring the telescopic link stiff end reduce, and first spring is in compressed state, when the flange slides to the conveyer belt from receiving the flitch, first spring promotes the expansion link's expansion end and removes to the direction of keeping away from measuring the telescopic link stiff end, make the inside volume increase of measuring the telescopic link stiff end, the transmission subassembly is according to the inside volume's of measuring the change control cooling chamber water pressure's of telescopic link stiff end size, make the start-up of water-cooling plant and the transportation state connection of flange.
Optionally, the transmission assembly comprises a push plate and a transmission telescopic rod; the pushing plate is arranged in the cooling cavity in a sliding manner; the pushing plate divides the cooling cavity into a water cavity and a water-free cavity; the transmission telescopic rod is horizontally arranged in the anhydrous cavity, the fixed end of the transmission telescopic rod is communicated with the fixed end of the measurement telescopic rod through a pipeline, and the movable end of the transmission telescopic rod is fixedly connected with the push plate; the inside level of transmission telescopic link stiff end is provided with the second spring, the one end of second spring with the expansion end fixed connection of transmission telescopic link, and the other end with the stiff end fixed connection of transmission telescopic link.
Through adopting above-mentioned technical scheme, when measuring the inside volume of telescopic link stiff end and reducing, the inside gas of measuring the telescopic link stiff end flows into the inside of transmission telescopic link stiff end through the pipeline, the inside volume increase of transmission telescopic link stiff end, the expansion end of transmission telescopic link moves to the direction of keeping away from the transmission telescopic link stiff end, the expansion end of transmission telescopic link promotes the push pedal and slides along backplate length direction in the cooling chamber, make there is inside water pressure increase of water cavity, when the inside volume increase of measurement telescopic link stiff end, the inside gas of transmission telescopic link stiff end flows into the inside of measurement telescopic link stiff end through the pipeline, the inside volume of transmission telescopic link stiff end reduces, the expansion end of transmission telescopic link moves to the direction that is close to the transmission telescopic link stiff end, make the inside water pressure of water cavity reduce, thereby realized according to the inside volume of measurement telescopic link stiff end's of change control cooling chamber water pressure's size.
Optionally, the water cooling assembly comprises a water inlet pipe and a water outlet pipe; the water inlet pipe and the water outlet pipe are arranged on the guard board and are communicated with the water cavity; one end of the water inlet pipe is provided with a water feeding valve, and one end of the water inlet pipe, which is far away from the guard plate, is provided with a water source; the second overflow valve is arranged on the drain pipe, and one end of the drain pipe, which is far away from the guard plate, is communicated with the outside.
By adopting the technical scheme, when the water pressure in the water cavity is increased, the water in the water cavity is discharged to the outside through the drain pipe; when the water pressure in the water cavity is reduced, the water inlet pipe is used for feeding water into the water cavity, so that the water cooling equipment can automatically change water according to the transportation state of the flange, and external energy input is not needed.
Optionally, a communication hole is formed in the side wall of the cooling cavity, and the communication hole is communicated with the outside; the guard plate is provided with communication components, the communication components are two and correspond to the guard plate one by one, and the communication components are used for isolating the communication holes.
Through adopting above-mentioned technical scheme, when the flange transportation, the inside steam of water cavity is discharged through the intercommunicating pore, when the automatic water change of water cavity has, the isolated intercommunicating pore of intercommunication subassembly for the inside water of water cavity is difficult for directly discharging from the intercommunicating pore.
Optionally, the communication assembly includes a telescoping plate and a first connecting tube; the telescopic plate is horizontally arranged, the fixed end of the telescopic plate is embedded in the guard plate, when the telescopic plate is in an extension state, the movable end of the telescopic plate is abutted to one side of the communication hole, and the communication hole is in an isolation state; a communication spring is horizontally arranged in the fixed end of the expansion plate, one end of the communication spring is fixedly connected with the movable end of the expansion plate, and the other end of the communication spring is fixedly connected with the fixed end of the expansion plate; one end of the first connecting pipe is communicated with the fixed end of the expansion plate, and the other end of the first connecting pipe is communicated with the fixed end of the measuring expansion rod; the fixed end of the expansion plate is provided with a second connecting pipe, one end of the second connecting pipe is communicated with the fixed end of the expansion plate, and the other end of the second connecting pipe is communicated with the fixed end of the transmission expansion rod; the second connecting pipe is provided with a first overflow valve, and gas in the fixed end of the expansion plate is used for flowing into the fixed end of the transmission expansion rod through the second connecting pipe.
Through adopting above-mentioned technical scheme, when measuring the inside volume reduction of telescopic link stiff end, measure the inside gas of telescopic link stiff end and flow into the stiff end of expansion plate through first connecting pipe, the inside volume increase of stiff end of expansion plate, the expansion plate's expansion end moves to the direction of keeping away from the expansion plate stiff end, the expansion plate's expansion end and the lateral wall butt of intercommunicating pore, thereby isolated intercommunicating pore, after the intercommunicating pore is in isolated state, measure the inside gas of telescopic link stiff end and flow into the inside of transmission telescopic link stiff end along first connecting pipe, second connecting pipe, when making the push pedal remove, the intercommunicating pore is isolated outside; when measuring the inside volume increase of telescopic link stiff end, the inside gas of telescopic link stiff end flows into the stiff end of measuring the telescopic link through first connecting pipe, and the expansion end of telescopic link moves to the direction that is close to the telescopic link stiff end, and the intercommunicating pore intercommunication is external with have the water cavity for cooling plant is when the flange transportation, and the intercommunicating pore is liable to be with the steam exhaust in the water cavity.
Optionally, the fixed end of the expansion plate is provided with a return pipe, one end of the return pipe is communicated with the fixed end of the expansion plate, and the other end of the return pipe is communicated with the fixed end of the transmission expansion rod; and the return pipe is provided with a one-way valve, and gas in the fixed end of the transmission telescopic rod is used for flowing into the fixed end of the telescopic plate through the return pipe.
Through adopting above-mentioned technical scheme, when measuring the volume increase of telescopic link stiff end, the gas of transmission telescopic link stiff end flows into the measurement telescopic link through back flow, first connecting pipe for the inside of measuring the telescopic link stiff end is refluxed to the gas in the transmission telescopic link stiff end.
Optionally, an air cooling cavity is formed in the guard plate; an exhaust hole is formed in one side of the guard plate and communicated with the air cooling cavity; the communication hole is communicated with the air cooling cavity; the air cooling assemblies are arranged on the guard plates, two air cooling assemblies are arranged and correspond to the guard plates one by one, and the air cooling assemblies are arranged in the air cooling cavities; the air cooling assembly comprises a motor and a fan; the motor is fixedly connected with one side of the air cooling cavity; the fan is fixedly connected with an output shaft of the motor.
Through adopting above-mentioned technical scheme, when the flange is in the conveyer belt transportation, the motor circular telegram drives the fan and rotates, and the steam in the water cavity reaches the forced air cooling chamber through the intercommunicating pore, discharges from the exhaust hole in forced air cooling chamber again to realized the discharge of the steam in the water cavity.
Optionally, a motor plug and a socket are arranged in the air cooling cavity, and the socket is electrically connected with an external power supply; the motor plug is matched with the socket for use, the motor plug is in sliding connection with the guard plate, and the motor plug is electrically connected with the motor; the motor plug is provided with delay components, the delay components are two and correspond to the guard plates one by one, and the delay components are used for controlling the on/off of the motor plug.
Through adopting above-mentioned technical scheme, when receiving the flitch, the flange is at the time, and delay assembly orders about motor plug and socket to link to each other for the motor circular telegram drives the fan and rotates, and after the flange transportation was accomplished, delay assembly orders about motor plug and socket disconnection, makes the motor outage, stops forced air cooling work, thereby makes forced air cooling equipment not need to last to start, has reduced the power consumption of work.
Optionally, the delay component comprises a first delay telescopic rod and a second delay telescopic rod; the first delay telescopic rod is vertically arranged in the cooling cavity; a delay spring is vertically arranged in the fixed end of the first delay telescopic rod, one end of the delay spring is fixedly connected with the movable end of the first delay telescopic rod, and the other end of the delay spring is fixedly connected with the fixed end of the first delay telescopic rod; a third connecting pipe is arranged at the bottom of the fixed end of the first delay telescopic rod, and the third connecting pipe is communicated with the first delay telescopic rod and the cooling cavity; the second time delay telescopic link is vertical to be set up, the stiff end of second time delay telescopic link with the expansion end fixed connection of first time delay telescopic link, the expansion end of second time delay telescopic link with motor plug fixed connection.
Through adopting above-mentioned technical scheme, there is the water level height of water cavity to rise, there is the inside of water cavity inflow first delay telescopic link stiff end through the third connecting pipe, the expansion end of first delay telescopic link moves to the direction of keeping away from first delay telescopic link stiff end, make motor plug and socket link to each other, there is the water level height of water cavity to reduce time, the inside water of first delay telescopic link stiff end flows into the inside of water cavity through the third connecting pipe, the expansion end of first delay telescopic link moves to the direction that is close to first delay telescopic link stiff end, first delay telescopic link moves, the expansion end of second delay telescopic link moves to the direction that is close to second delay telescopic link stiff end, after the flange transportation is accomplished, the second delay telescopic link stops moving, first delay telescopic link continues to move, motor plug and socket disconnection, thereby the start-up of automatic control forced air cooling equipment has been realized.
In summary, the present application includes at least one of the following beneficial technical effects:
the water cooling equipment automatically controls the switch according to the transportation state of the flange by arranging the measuring assembly;
the transmission assembly and the water cooling assembly are arranged, so that the water cooling equipment does not need external energy input;
through setting up time delay subassembly for air-cooled equipment can automatic control switch.
Drawings
FIG. 1 is a schematic diagram of an embodiment of the present application;
FIG. 2 is a cross-sectional view for showing the internal structure of the measuring telescopic rod in the embodiment of the present application;
FIG. 3 is a cross-sectional view of an embodiment of the present application;
FIG. 4 is an enlarged view of a portion of FIG. 3 at A;
FIG. 5 is a partial enlarged view at B in FIG. 3;
fig. 6 is a partial enlarged view at C in fig. 3.
Reference numerals illustrate:
1. a conveyor belt; 11. a conveyor belt support;
2. a guard board; 21. a cooling chamber; 211. a water cavity is formed; 212. the water cavity is not formed; 213. a communication hole; 22. an air cooling cavity; 221. an exhaust hole;
3. a measurement assembly; 31. a receiving plate; 32. a slide block; 33. measuring a telescopic rod; 331. a first spring;
4. a transmission assembly; 41. a push plate; 42. a transmission telescopic rod; 421. a second spring; 43. a second connection pipe; 431. a first overflow valve; 44. a return pipe; 441. a one-way valve;
5. a water cooling assembly; 51. a water inlet pipe; 511. a water feeding valve; 52. a drain pipe; 521. a second overflow valve;
6. a communication assembly; 61. a telescoping plate; 611. a communication spring; 62. a first connection pipe;
7. an air cooling assembly; 71. a motor; 711. a motor plug; 712. a socket; 72. a fan;
8. a delay component; 81. a first delay telescopic rod; 811. a delay spring; 812. a third connection pipe; 82. and a second delay telescopic rod.
Detailed Description
The application is described in further detail below with reference to fig. 1-6.
The embodiment of the application discloses a conveying device for flange part machining. Referring to fig. 1 and 2, a transporting device for flange part processing includes a conveyor belt 1, a guard plate 2, a measuring assembly 3, a transmission assembly 4, and a water cooling assembly 5. The guard plates 2 are arranged on two sides of the conveyor belt 1, a cooling cavity 21 is formed in the guard plates 2, and water is filled in the cooling cavity 21. The measuring assembly 3 is used for detecting the flange transportation state and outputting detection signals. The transmission component 4 and the water cooling component 5 are respectively provided with two and are in one-to-one correspondence with the guard plate 2. The transmission assembly 4 is arranged to respond to the detection signal and to control the level of the water pressure in the cooling chamber 21. The water cooling assembly 5 is used for responding to the water pressure in the cooling cavity 21 and controlling the replacement of the water in the cooling cavity 21.
When the flange is transported, the measuring component 3 detects the transportation state of the flange and transports the flange onto the conveyor belt 1, the transmission component 4 controls the water pressure in the cooling cavity 21 according to the detection signal of the measuring component 3, and the water cooling component 5 controls the replacement of water in the cooling cavity 21 according to the water pressure in the cooling cavity 21, so that the cooling equipment replaces the internal cooling water according to the transportation state of the flange.
Referring to fig. 3, the guard plate 2 is in a rectangular plate shape and horizontally arranged, and the guard plate 2 is provided in two and fixedly arranged on both sides of the conveyor support 11, respectively. An air cooling cavity 22 is formed in the guard plate 2, and the air cooling cavity 22 is located right above the cooling cavity 21. The side wall of the cooling chamber 21 is provided with a communication hole 213, and the communication hole 213 is rectangular and penetrates the side wall between the cooling chamber 21 and the air cooling chamber 22. The top of the guard plate 2 is provided with an exhaust hole 221, and the exhaust hole 221 is in a circular hole shape and is communicated with the air cooling cavity 22.
Referring to fig. 3 to 6, the guard plate 2 is further provided with a communication assembly 6, an air cooling assembly 7 and a delay assembly 8. The communication assemblies 6 are arranged in two and are in one-to-one correspondence with the guard plates 2, and the communication assemblies 6 are used for isolating the communication holes 213. The air cooling assemblies 7 are arranged in two and are in one-to-one correspondence with the guard plates 2, and the air cooling assemblies 7 are used for discharging hot air in the water cavity 211. The delay components 8 are arranged in two and are in one-to-one correspondence with the guard plates 2, and the delay components 8 are used for controlling the switch of the air cooling component 7.
Referring to fig. 1, the measuring assembly 3 includes a receiving plate 31, a slider 32, and a measuring telescopic rod 33. The receiving plate 31 is rectangular plate-shaped and is obliquely arranged, the receiving plate 31 is positioned above the conveyor belt 1, and one side of the receiving plate is hinged with one side of the conveyor belt bracket 11. The measuring telescopic rod 33 is arranged vertically and is located below the receiving plate 31. The sliding block 32 is rectangular and is hinged with one side of the movable end of the measuring telescopic rod 33, which is close to the material receiving plate 31, the sliding block 32 is in sliding connection with the material receiving plate 31, and the sliding direction is the inclined direction of the material receiving plate 31. The inside of measuring telescopic link 33 stiff end is vertical to be provided with first spring 331, and the one end of first spring 331 and the expansion end fixed connection of measuring telescopic link 33, and the other end and the stiff end fixed connection of measuring telescopic link 33.
During flange transportation, the staff places the flange after processing on receiving the flitch 31, and the flange slides to conveyer belt 1 along the incline direction of receiving the flitch 31, when the flange was placed to receiving the flitch 31, the gravity of flange self is extruded to receiving flitch 31, measure telescopic link 33 to make the expansion end shrink of measuring telescopic link 33, the inside volume of telescopic link stiff end reduces, and first spring 331 is in compressed state, when the flange from receiving the flitch 31 landing to conveyer belt 1, measures the interior first spring 331 of telescopic link 33 and resets, makes the expansion end extension of measuring telescopic link 33, the inside volume increase of telescopic link stiff end.
Referring to fig. 1 and 4, the communication assembly 6 includes a telescopic plate 61 and a first connection pipe 62. The expansion plate 61 is horizontally arranged, the fixed end is embedded in the guard plate 2, the movable end of the expansion plate 61 is slidably connected with the communication hole 213 along the horizontal direction, the end face of the movable end of the expansion plate 61, which is far away from the fixed end of the expansion plate 61, is abutted against the side wall of the communication hole 213, and the communication hole 213 is in an isolated state. The inside parallel arrangement of expansion plate 61 stiff end has communication spring 611, and the one end of communication spring 611 and expansion plate 61's movable end fixed connection, and the other end and expansion plate 61's stiff end fixed connection. One end of the first connecting pipe 62 communicates with the fixed end of the measurement telescoping rod 33, and the other end communicates with the fixed end of the telescoping plate 61.
When the volume inside the fixed end of the measuring telescopic rod 33 is reduced, the gas inside the fixed end of the measuring telescopic rod 33 flows into the fixed end of the telescopic plate 61 through the first connecting pipe 62, the movable end of the telescopic plate 61 stretches, and the end face of the movable end of the telescopic plate 61, which is far away from the fixed end of the telescopic plate 61, is abutted against the side wall of the communication hole 213, so that the communication hole 213 is completely isolated. When the volume inside the fixed end of the measuring telescopic rod 33 increases, the gas inside the fixed end of the telescopic plate 61 flows into the fixed end of the measuring telescopic rod 33 through the first connecting pipe 62, the movable end of the telescopic plate 61 contracts, the communication hole 213 communicates with the outside, and the hot gas inside the cooling chamber 21 is easily discharged out of the outside through the communication hole 213.
Referring to fig. 3 and 4, the drive assembly 4 includes a push plate 41, a drive expansion link 42, a second connecting tube 43, and a return tube 44. The push plate 41 is rectangular plate-shaped, is matched with the section of the cooling cavity 21 in the length direction, is vertically arranged, and is in sliding connection with the cooling cavity 21 along the length direction of the guard plate 2. The push plate 41 divides the cooling chamber 21 into a water-containing chamber 211 and a water-free chamber 212, the communication hole 213 is positioned on the side wall of the water-containing chamber 211, and the transmission telescopic rod 42 is positioned in the water-free chamber 212 and horizontally arranged. The movable end of the transmission telescopic rod 42 is fixedly connected with the push plate 41, and the fixed end of the transmission telescopic rod 42 is fixedly connected with the side wall of the anhydrous cavity 212. The fixed end of the transmission telescopic rod 42 is horizontally provided with a second spring 421, one end of the second spring 421 is fixedly connected with the movable end of the transmission telescopic rod 42, and the other end of the second spring 421 is fixedly connected with the fixed end of the transmission telescopic rod 42.
One end of the second connecting pipe 43 is communicated with the fixed end of the telescopic plate 61, the other end of the second connecting pipe is communicated with the fixed end of the transmission telescopic rod 42, the first overflow valve 431 is arranged on the second connecting pipe 43, and gas communicated with the inside of the fixed end of the telescopic plate 61 flows into the inside of the fixed end of the transmission telescopic rod 42 through the second connecting pipe 43. One end of the return pipe 44 is communicated with the fixed end of the expansion plate 61, and the other end is communicated with the fixed end of the transmission expansion link 42, a one-way valve 441 is arranged on the return pipe 44, and gas inside the fixed end of the transmission expansion link 42 can flow into the inside of the fixed end of the expansion plate 61 through the return pipe 44.
Referring to fig. 3 and 6, the water cooling assembly 5 includes a water inlet pipe 51 and a water outlet pipe 52. The inlet tube 51 fixed mounting is on backplate 2, and is close to backplate 2 one end and has the water cavity 211 intercommunication, and the one end that the inlet tube 51 was kept away from backplate 2 is equipped with the water source, and the water valve 511 is installed to the other end. The drain pipe 52 is fixedly arranged on the guard plate 2, one end, close to the guard plate 2, is communicated with the water cavity 211, one end, far away from the guard plate 2, of the drain pipe 52 is communicated with the outside, the second overflow valve 521 is arranged on the drain pipe 52, and water in the water cavity 211 can flow out of the water cavity 211 through the drain pipe 52.
When the air pressure in the fixed end of the expansion plate 61 is increased, the second overflow valve 521 is opened, so that the air in the fixed end of the expansion plate 61 flows into the fixed end of the transmission expansion link 42 through the second connecting pipe 43, the volume of the fixed end of the transmission expansion link 42 is increased, the second spring 421 is in a stretched state, the movable end of the transmission expansion link 42 is stretched, the push plate 41 is pushed to slide in the cooling cavity 21 along the length direction of the guard plate 2, the water pressure in the water cavity 211 is increased, the second overflow valve 521 installed on the drain pipe 52 is opened, the water in the water cavity 211 flows out of the water cavity 211 through the drain pipe 52, the air pressure in the fixed end of the expansion plate 61 is reduced, the second spring 421 is reset, the movable end of the transmission expansion link 42 is contracted, the water pressure in the water cavity 211 is reduced, the water level is reduced, the water feeding valve 511 is opened, the water inlet pipe 51 automatically feeds water into the water cavity 211, and automatic replacement of the water in the water cavity 211 is completed.
Referring to fig. 3, the air cooling assembly 7 includes a motor 71 and a fan 72, and the motor 71 is horizontally disposed and fixedly installed inside the air cooling chamber 22. The fan 72 is coaxially arranged with the output shaft of the motor 71, and the fan 72 is fixedly connected with the output shaft of the motor 71.
Referring to fig. 5, a socket 712 is fixedly installed at the top of the air cooling chamber 22, and the socket 712 is electrically connected with an external power source. The inside motor plug 711 that is provided with of forced air cooling chamber 22, motor plug 711 and backplate 2 are along vertical direction sliding connection, and use with the socket 712 cooperation, and motor plug 711 is connected with the motor 71 electricity.
Referring to fig. 5 and 6, the delay assembly 8 includes a first delay telescoping rod 81 and a second delay telescoping rod 82. The inside at cooling chamber 21 is vertically set up to first delay telescopic link 81, the stiff end of first delay telescopic link 81 and the lateral wall fixed connection of cooling chamber 21, the stiff end of first delay telescopic link 81 is vertical to be provided with delay spring 811, delay spring 811's one end and the expansion end fixed connection of first delay telescopic link 81, and the stiff end fixed connection of the other end and first delay telescopic link 81, the bottom of the stiff end of first delay telescopic link 81 is provided with third connecting pipe 812, third connecting pipe 812 intercommunication first delay telescopic link 81 and cooling chamber 21. The second time delay telescopic link 82 is vertical to be set up, and the top fixed connection of stiff end and first time delay telescopic link 81 expansion end, the top of second time delay telescopic link 82 expansion end and motor plug 711 fixed connection.
When the transmission telescopic rod 42 is in an elongation state, the water level in the water cavity 211 rises, water in the water cavity 211 flows into the inside of the fixed end of the first delay telescopic rod 81 through the third connecting pipe 812, the movable end of the first delay telescopic rod 81 is in an elongation state, the delay spring 811 is in a stretching state, the movable end of the second delay telescopic rod 82 is in a contraction state, the motor plug 711 is inserted on the socket 712, the motor 71 is electrified to drive the fan 72 to rotate, hot air in the water cavity 211 flows into the air cooling cavity 22 through the communication hole 213 and is discharged from the air outlet 221, when water in the water cavity 211 is discharged, the delay spring 811 is reset, the movable end of the first delay telescopic rod 81 is contracted, the movable end of the second delay telescopic rod 82 is elongated when the first delay telescopic rod 81 is contracted, and the motor plug 711 and the socket 712 are disconnected after a certain time.
The implementation principle of the conveying device for flange part machining provided by the embodiment of the application is as follows: when the flange is transported, the worker places the processed flange on the material receiving plate 31, and the flange slides onto the conveyor belt 1 along the inclined direction of the material receiving plate 31. And the flange is extruded to the material plate 31 and the measuring telescopic rod 33, so that the gas in the fixed end of the measuring telescopic rod 33 flows into the telescopic plate 61 through the first connecting pipe 62, and the movable end of the telescopic plate 61 extends to completely isolate the communication hole 213.
After the expansion plate 61 is in an elongation state, the first overflow valve 431 is opened, gas in the expansion plate 61 flows into the fixed end of the transmission expansion link 42 through the second connecting pipe 43, the movable end of the transmission expansion link 42 stretches, and the push plate 41 is pushed to slide along the length direction of the guard plate 2, so that the water pressure in the water cavity 211 increases to open the second overflow valve 521, and water in the water cavity 211 is discharged out of the water cavity 211 through the drain pipe 52.
After the water pressure in the water cavity 211 increases, the water in the water cavity 211 flows into the fixed end of the first time delay telescopic rod 81 through the third connecting pipe 812, the movable end of the first time delay telescopic rod 81 stretches, the motor plug 711 is connected with the socket 712, the motor 71 is electrified, and the output shaft of the motor 71 drives the fan 72 to rotate.
After the flange slides to the conveyor belt 1, the second spring 421 resets and drives the movable end of the transmission telescopic rod 42 to shrink, the gas in the fixed end of the transmission telescopic rod 42 flows into the fixed end of the telescopic plate 61 along the return pipe 44, the first spring 331 resets and drives the movable end of the telescopic plate 61 to shrink, the gas in the fixed end of the telescopic plate 61 flows into the fixed end of the measurement telescopic rod 33 along the first connecting pipe 62, the water pressure in the water cavity 211 is reduced, the water feeding valve 511 is opened, the water feeding pipe 51 automatically feeds water into the water cavity 211, the communication hole 213 is communicated with the outside, the delay spring 811 resets and drives the movable end of the first delay telescopic rod 81 to shrink.
When the first time delay telescopic rod 81 contracts, the movable end of the second time delay telescopic rod 82 stretches, after the flange is transported to the collecting box, the second time delay telescopic rod 82 stops working, the first time delay telescopic rod 81 continues to work, the motor plug 711 is disconnected with the socket 712, the motor 71 is powered off, the fan 72 stops working, and therefore the cooling equipment automatically stops air cooling working after the flange is transported, and energy consumption of the transporting device for flange part machining is reduced.
The above embodiments are not intended to limit the scope of the present application, so: all equivalent changes in structure, shape and principle of the application should be covered in the scope of protection of the application.
Claims (7)
1. The utility model provides a conveyer for flange part processing, includes conveyer belt (1) and backplate (2), backplate (2) are provided with two, and set up respectively conveyer belt (1) both sides, backplate (2) and conveyer belt support (11) fixed connection, its characterized in that: the device also comprises a measuring assembly (3), a transmission assembly (4) and a water cooling assembly (5); the measuring assembly (3) is positioned on one side of the conveyor belt (1), and the measuring assembly (3) is used for detecting the transportation state of the flange and outputting a detection signal; a cooling cavity (21) is formed in the guard plate (2), and water is filled in the cooling cavity (21); the transmission assembly (4) is positioned in the cooling cavity (21), the transmission assembly (4) is provided with two groups and corresponds to the guard plates (2) one by one, and the transmission assembly (4) is used for responding to the detection signal output by the measurement assembly (3) and controlling the water pressure in the cooling cavity (21); the water cooling assemblies (5) are positioned in the cooling cavity (21), the water cooling assemblies (5) are provided with two groups and are in one-to-one correspondence with the guard plates (2), and the water cooling assemblies (5) are used for responding to the water pressure in the cooling cavity (21) and controlling the replacement of water in the cooling cavity (21); the measuring assembly (3) comprises a receiving plate (31) and a measuring telescopic rod (33); the material receiving plate (31) is obliquely arranged and is positioned above the conveyor belt (1), and one side of the material receiving plate (31) is hinged with one side of the conveyor belt bracket (11); the measuring telescopic rod (33) is vertically arranged and is positioned below the receiving plate (31); a sliding block (32) is hinged to the movable end of the measuring telescopic rod (33), and the sliding block (32) is connected with one side of the material receiving plate (31) in a sliding manner; a first spring (331) is vertically arranged in the fixed end of the measuring telescopic rod (33), one end of the first spring (331) is fixedly connected with the movable end of the measuring telescopic rod (33), and the other end of the first spring is fixedly connected with the fixed end of the measuring telescopic rod (33); the transmission assembly (4) comprises a push plate (41) and a transmission telescopic rod (42); the push plate (41) is arranged in the cooling cavity (21) in a sliding way; the pushing plate (41) divides the cooling cavity (21) into a water cavity (211) and a water-free cavity (212); the transmission telescopic rod (42) is horizontally arranged in the anhydrous cavity (212), the fixed end of the transmission telescopic rod (42) is communicated with the fixed end of the measurement telescopic rod (33) through a pipeline, and the movable end of the transmission telescopic rod (42) is fixedly connected with the push plate (41); a second spring (421) is horizontally arranged in the fixed end of the transmission telescopic rod (42), one end of the second spring (421) is fixedly connected with the movable end of the transmission telescopic rod (42), and the other end of the second spring is fixedly connected with the fixed end of the transmission telescopic rod (42); the water cooling assembly (5) comprises a water inlet pipe (51) and a water outlet pipe (52); the water inlet pipe (51) and the water outlet pipe (52) are arranged on the guard plate (2) and are communicated with the water cavity (211); one end of the water inlet pipe (51) is provided with a water feeding valve (511), and one end of the water inlet pipe (51) far away from the guard plate (2) is provided with a water source; the second overflow valve (521) is arranged on the drain pipe (52), and one end of the drain pipe (52) away from the guard plate (2) is communicated with the outside.
2. The transportation device for flange part machining according to claim 1, characterized in that: a communication hole (213) is formed in the side wall of the cooling cavity (21), and the communication hole (213) is communicated with the outside; the guard board (2) is provided with communication components (6), the communication components (6) are arranged in two and correspond to the guard board (2) one by one, and the communication components (6) are used for isolating the communication holes (213).
3. A transportation device for flange part machining according to claim 2, characterized in that: the communication assembly (6) comprises a telescopic plate (61) and a first connecting pipe (62); the telescopic plate (61) is horizontally arranged, the fixed end of the telescopic plate is embedded in the guard plate (2), when the telescopic plate (61) is in an extension state, the movable end of the telescopic plate (61) is abutted to one side of the communication hole (213), and the communication hole (213) is in an isolation state; a communication spring (611) is horizontally arranged in the fixed end of the expansion plate (61), one end of the communication spring (611) is fixedly connected with the movable end of the expansion plate (61), and the other end of the communication spring is fixedly connected with the fixed end of the expansion plate (61); one end of the first connecting pipe (62) is communicated with the fixed end of the expansion plate (61), and the other end of the first connecting pipe is communicated with the fixed end of the measuring expansion rod (33); the fixed end of the expansion plate (61) is provided with a second connecting pipe (43), one end of the second connecting pipe (43) is communicated with the fixed end of the expansion plate (61), and the other end of the second connecting pipe is communicated with the fixed end of the transmission expansion rod (42); the second connecting pipe (43) is provided with a first overflow valve (431), and gas in the fixed end of the expansion plate (61) flows into the fixed end of the transmission expansion link (42) through the second connecting pipe (43).
4. A transportation device for flange part machining according to claim 3, characterized in that: the fixed end of the expansion plate (61) is provided with a return pipe (44), one end of the return pipe (44) is communicated with the fixed end of the expansion plate (61), and the other end of the return pipe is communicated with the fixed end of the transmission expansion rod (42); the return pipe (44) is provided with a one-way valve (441), and gas in the fixed end of the transmission telescopic rod (42) flows into the fixed end of the telescopic plate (61) through the return pipe (44).
5. The transportation device for flange part machining according to claim 4, wherein: an air cooling cavity (22) is formed in the guard board (2); an exhaust hole (221) is formed in one side of the guard plate (2), and the exhaust hole (221) is communicated with the air cooling cavity (22); the communication hole (213) is communicated with the air cooling cavity (22); the air cooling assemblies (7) are arranged on the guard plates (2), the number of the air cooling assemblies (7) is two, the air cooling assemblies are in one-to-one correspondence with the guard plates (2), and the air cooling assemblies (7) are arranged in the air cooling cavities (22); the air cooling assembly (7) comprises a motor (71) and a fan (72); the motor (71) is fixedly connected with one side of the air cooling cavity (22); the fan (72) is fixedly connected with an output shaft of the motor (71).
6. The transportation device for flange part machining according to claim 5, characterized in that: a motor plug (711) and a socket (712) are arranged in the air cooling cavity (22), and the socket (712) is electrically connected with an external power supply; the motor plug (711) is matched with the socket (712), the motor plug (711) is in sliding connection with the guard plate (2), and the motor plug (711) is electrically connected with the motor (71); the motor plug (711) is provided with delay components (8), the delay components (8) are arranged in two and correspond to the guard plates (2) one by one, and the delay components (8) are used for controlling the on-off of the motor plug (711).
7. The transportation device for flange part machining according to claim 6, characterized in that: the delay component (8) comprises a first delay telescopic rod (81) and a second delay telescopic rod (82); the first delay telescopic rod (81) is vertically arranged in the cooling cavity (21); a delay spring (811) is vertically arranged in the fixed end of the first delay telescopic rod (81), one end of the delay spring (811) is fixedly connected with the movable end of the first delay telescopic rod (81), and the other end of the delay spring is fixedly connected with the fixed end of the first delay telescopic rod (81); a third connecting pipe (812) is arranged at the bottom of the fixed end of the first delay telescopic rod (81), and the third connecting pipe (812) is communicated with the first delay telescopic rod (81) and the cooling cavity (21); the second time delay telescopic rod (82) is vertically arranged, the fixed end of the second time delay telescopic rod (82) is fixedly connected with the movable end of the first time delay telescopic rod (81), and the movable end of the second time delay telescopic rod (82) is fixedly connected with the motor plug (711).
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| CN202311091624.4A CN116788756B (en) | 2023-08-29 | 2023-08-29 | Conveyer is used in flange part processing |
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