CN112265197A - Intelligent temperature control system for butterfly-shaped lead-in optical cable - Google Patents

Abstract

The invention relates to the field of optical cable manufacturing, and particularly discloses an intelligent temperature control system for a butterfly-shaped leading-in optical cable, which comprises a groove body, wherein a plurality of baffles are arranged in the groove body to divide the inside of the groove body into a plurality of water storage tanks, the water storage tanks are used for containing water with different temperatures, the temperatures of the water in the adjacent water storage tanks are set to be step temperatures, a temperature adjusting device is arranged in the groove body, the temperature adjusting device comprises a driving device, the output end of the driving device is connected with a rotating shaft, the intelligent temperature control system further comprises a water conveying pipe, the water conveying pipe is arranged along the groove body and penetrates through the baffles, the rotating shaft is arranged in the water conveying pipe, and. The invention has the advantages that the tank body is divided into a plurality of water storage tanks, the plurality of water storage tanks are filled with cooling water with different temperatures, the optical cable is cooled by gradient arrangement, and the cooling water with low temperature is conveyed into the water storage tank with high temperature water by the temperature adjusting device for cooling through the temperature adjusting device arranged in the water storage tanks, so that the mixed temperature is small in change and easy to control.

Description

Intelligent temperature control system for butterfly-shaped lead-in optical cable

Technical Field

The invention relates to the field of optical cable manufacturing, in particular to an intelligent temperature control system for a butterfly-shaped drop optical cable.

Background

At present, optical cables are increasingly and widely applied, the butterfly-shaped leading-in optical cable is an optical cable for common indoor communication, the main function is used for transmitting communication signals, the optical surface of the optical cable is at a temperature higher than 170 ℃ after plastic sheathing, the plastic sheathing is in an unstable state and can be taken up only after being solidified after being cooled, the temperature of the optical cable needs to be reduced to 50 ℃ from 170 ℃ when being cooled, the constant temperature of the existing cooling water tank is 50 +/-5 ℃, the temperature of the water tank is not easy to control, the degree of a section of compact package of the optical fibers in the optical cable is different, and the tensile test of the butterfly-shaped leading-in optical.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provides an intelligent temperature control system for a butterfly-shaped drop cable.

The purpose of the invention is realized by the following technical scheme: an intelligent temperature control system for a butterfly-shaped lead-in optical cable comprises a tank body, wherein a plurality of baffles are arranged in the tank body to divide the interior of the tank body into a plurality of water storage tanks, the plurality of water storage tanks are used for containing water with different temperatures, the temperature of the water in the adjacent water storage tanks is set to be a step temperature, a temperature adjusting device is arranged in the tank body and comprises a driving device, the output end of the driving device is connected with a rotating shaft, the intelligent temperature control system further comprises a water conveying pipe, the water conveying pipe is arranged along the tank body and penetrates through the plurality of baffles, the rotating shaft is arranged in the water conveying pipe, a plurality of water conveying mechanisms are arranged on the rotating shaft, each water conveying mechanism comprises an electromagnetic clutch, a sleeve and a spiral blade, the inner ring of the electromagnetic clutch is fixed on the rotating shaft, the sleeve is sleeved on the rotating shaft, and one end of the sleeve is fixedly connected with the, the helical blade is arranged on the outer side wall of the sleeve, wherein the outer edge of the helical blade is attached to the inner wall of the water conveying pipe;

the raceway be located the lateral wall of helical blade one end and seted up the water inlet, the raceway has seted up the apopore on being located the lateral wall of the helical blade other end, the raceway be connected with water outlet device through the apopore, water outlet device sets up in the aqua storage tank, the pivot is rotated and is driven helical blade and carry helical blade's water in the aqua storage tank through the water inlet other end and flow through the apopore, the water that flows through the apopore flows into in the aqua storage tank that the temperature that sets up is higher than the water inlet temperature through water outlet device.

Specifically, the two ends of the spiral blade on the sleeve are provided with baffle rings.

Specifically, a water conveying mechanism is arranged in the water conveying pipe in each water storage tank area.

Specifically, one end of the sleeve, which is far away from the electromagnetic clutch, is rotatably connected with the rotating shaft through a bearing.

Specifically, a dynamic sealing device is arranged between the two ends of the sleeve and the rotating shaft.

Specifically, the baffle is provided with a threading hole.

Specifically, the play water installation include the rivers pipe, the one end of rivers pipe is passed through apopore and raceway intercommunication, the other end of rivers pipe is connected with the shunt tubes, follow the shunt tubes axial and seted up a plurality of diffluence spouts on the shunt tubes, the shunt tubes is connected with a plurality of drain pipes through the diffluence spout.

Specifically, the lateral wall of helical blade one end on set up the apopore be provided with two, two apopores are equallyd divide and do not are connected with a rivers pipe, wherein, the shunt tubes be provided with two, two shunt tubes connect different rivers pipes respectively, two the shunt tubes sets up the both sides at the aqua storage tank.

Specifically, the water storage tank is internally provided with two supports, the liquid outlet pipe is fixed on the supports, and the extension line of the liquid outlet end of the liquid outlet pipe passes through the moving path of the optical cable.

The temperature detection module is arranged in the water storage tank and protects a plurality of temperature sensors which are uniformly distributed and arranged below the moving path of the optical cable.

The invention has the following advantages:

1. the invention divides the tank body into a plurality of water storage tanks, the plurality of water storage tanks are filled with cooling water with different temperatures, the optical cable is cooled through gradient arrangement, and the cooling water with low temperature is conveyed into the water storage tank with high temperature water through the temperature adjusting device to be cooled through the temperature adjusting device arranged in the water storage tanks, so that the mixed temperature is small in change and easy to control.

2. The purpose of arranging the electromagnetic clutch in the invention is to realize independent regulation and control of the temperature of each water storage tank, because the driving device drives the rotating shaft to rotate all the time, if the temperature of the water in a certain water storage tank is not required to be regulated and controlled temporarily, the rotating shaft is always connected with the sleeve, so that the water enters the water storage tank all the time to be cooled, the temperature is not controlled, and the transmission connection between the rotating shaft and the sleeve is required to be disconnected under the condition, so the sleeve in the scheme is connected with the rotating shaft through the electromagnetic clutch, the transmission connection between the rotating shaft and the sleeve can be disconnected by electrifying and disconnecting the electromagnetic clutch when the sleeve is required to be disconnected, and the temperature in each water storage tank can be regulated and controlled independently.

Drawings

FIG. 1 is a schematic view of the structure of the trough of the present invention;

FIG. 2 is a schematic structural diagram of a temperature control device according to the present invention;

FIG. 3 is a schematic view of a shunt tube arrangement according to the present invention;

in the figure: 1-driving device, 2-speed reducer, 3-liquid outlet pipe, 4-groove body, 5-shunt pipe, 6-temperature regulating device, 7-baffle, 8-water storage groove, 9-threading hole, 10-bracket, 11-rotating shaft, 12-electromagnetic clutch, 13-sleeve, 14-bearing, 15-water outlet hole, 16-helical blade, 17-dynamic sealing device, 18-water conveying pipe and 19-retaining ring.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the detailed description and specific examples, while indicating the preferred embodiment of the invention, are intended for purposes of illustration only and are not intended to limit the scope of the invention. The components of embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present invention, presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments of the present invention without making any creative effort, shall fall within the protection scope of the present invention.

It is noted that relational terms such as "first" and "second," and the like, may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element.

The invention will be further described with reference to the accompanying drawings, but the scope of the invention is not limited to the following.

As shown in fig. 1 to 3, an intelligent temperature control system for a butterfly-shaped lead-in optical cable comprises a tank body 4, wherein a plurality of baffles 7 are arranged in the tank body 4 to divide the interior of the tank body 4 into a plurality of water storage tanks 8, the plurality of water storage tanks 8 are used for containing water with different temperatures, the temperature of the water in the adjacent water storage tanks 8 is set to be a step temperature, a temperature adjusting device 6 is arranged in the tank body 4, the temperature adjusting device 6 comprises a driving device 1, the output end of the driving device 1 is connected with a rotating shaft 11, the intelligent temperature control system further comprises a water conveying pipe 18, the water conveying pipe 18 is arranged along the tank body 4, the water conveying pipe 18 penetrates through the plurality of baffles 7, the rotating shaft 11 is arranged in the water conveying pipe 18, a plurality of water conveying mechanisms are arranged on the rotating shaft 11, the water conveying mechanisms comprise an electromagnetic clutch 12, a sleeve 13 and a helical blade 16, the inner ring of the, the sleeve 13 is sleeved on the rotating shaft 11, one end of the sleeve is fixedly connected with the outer ring of the electromagnetic clutch 12, the helical blade 16 is arranged on the outer side wall of the sleeve 13, and the outer edge of the helical blade 16 is attached to the inner wall of the water pipe 18;

the utility model discloses a water storage tank, including water storage tank 8, shaft 11, raceway 18, water outlet device, pivot 11, the raceway 18 be located the lateral wall of 16 one ends of helical blade and seted up the water inlet, raceway 18 has seted up apopore 15 on being located the lateral wall of the 16 other ends of helical blade, raceway 18 be located the lateral wall of the 16 other ends of helical blade, water outlet device sets up in water storage tank 8, pivot 11 rotates and drives helical blade 16 and carry the water in water storage tank 8 through the water inlet and pass through apopore 15 and flow out through helical blade 16's the other end, the water that flows out through apopore 15 flows into in the water storage tank 8 that the temperature that. The optical cable needs to enter a cooling water tank for cooling after an outer sleeve is extruded and molded by an extruding machine, so that the outer sleeve tightly wraps the optical fiber, the temperature of water in the existing cooling water tank is mostly set to be 50 +/-5 ℃ of constant temperature, then cooling water enters through one end of the cooling water tank, and warm water is discharged from the other end of the cooling water tank for circulation, so that the temperature is not easy to control, the different degrees of one section of the tight wrapping of the optical fiber in the outer sleeve are easily caused, the tensile test of a butterfly-shaped leading-in optical cable product is seriously influenced, and the control of the water temperature is a key step for influencing the molding quality; the scheme divides the tank body 4 into a plurality of water storage tanks 8 by arranging a plurality of baffles 7, four water storage tanks 8 are preferably arranged in the scheme, wherein the water temperature in the water storage tanks 8 is set to 80 ℃, 70 ℃, 60 ℃ and 50 ℃ from the entrance end of the optical cable to the exit end of the optical cable in sequence, the optical cable is cooled in a step temperature mode, the temperature of the optical cable after extrusion molding is 170 ℃, the optical cable firstly enters the water storage tank 8 with the water temperature of 80 ℃ for cooling, and then sequentially enters the water storage tanks 8 of 70 ℃, 8 and 50 ℃ and 8, the purpose of the arrangement is to adopt a gradient cooling mode, so that the optical cable has a transition process during cooling, the jacket of the optical cable can be wrapped and compacted and keep consistency during cooling, in addition, a temperature regulating device 6 is also arranged in the tank body 4 to regulate the temperature in the water storage tanks 8, the temperature regulating mode in the scheme is to mix low-temperature water and high-temperature water for cooling, the method specifically comprises the steps that water in a 70 ℃ water storage tank 8 is conveyed into a 80 ℃ water storage tank 8 to be mixed with 80 ℃ water to achieve the purpose of cooling, water in a 60 ℃ water storage tank 8 is conveyed into the 70 ℃ water storage tank 8 to be mixed with 70 ℃ water to achieve cooling, water in a 50 ℃ water storage tank 8 is conveyed into the 60 ℃ water storage tank 8 to be mixed with 60 ℃ water to achieve cooling, cooling water is introduced into the 50 ℃ water storage tank 8 to be cooled, and the two water with small temperature difference are mixed in such a way, so that the temperature change is easier to control, if normal temperature water is directly introduced, the temperature difference is too large, the change temperature curve of the mixed water is steep, and the control is difficult; in the scheme, a water delivery mechanism is arranged in a water delivery pipe 18 in each water storage tank 8 and is used for delivering water in the water storage tank 8 into the water storage tank 8 with the temperature higher than the temperature of the water storage tank, the water delivery mechanism is driven by a driving device, the output end of the driving device is connected with a rotating shaft 11, the water delivery mechanism can be driven by being in transmission connection with the rotating shaft 11, wherein, a sleeve 13 in the water delivery mechanism is connected with a rotating shaft 11 through an electromagnetic clutch 12, when the rotating shaft 11 rotates, power is transmitted to the sleeve 13 through the electromagnetic clutch 12, then the sleeve 13 drives a helical blade 16 to rotate to deliver water, wherein, water enters the water pipe 18 through a water inlet arranged on the water pipe 18, the water inlet is not shown in the figure, the water entering the water pipe 18 through the water inlet is conveyed to the other end of the helical blade 16 through the rotation of the helical blade 16, and then is output through the water outlet 15 and flows into other water storage tanks 8.

Go out water installation include the rivers pipe, the one end of rivers pipe is passed through apopore 15 and 18 intercommunications of raceway, the other end of rivers pipe is connected with shunt tubes 5, a plurality of diffluence spouts have been seted up along 5 axial of shunt tubes on shunt tubes 5, shunt tubes 5 are connected with a plurality of drain pipes 3 through the diffluence spout, the lateral wall of 16 one ends of helical blade on set up apopore 15 be provided with two, two apopores 15 are equallyd divide and do not are connected with a rivers pipe, wherein, shunt tubes 5 be provided with two, two different rivers pipes are connected respectively to two shunt tubes 5, two shunt tubes 5 set up the both sides at aqua storage tank 8, aqua storage tank 8 in all be provided with two supports 10, drain pipe 3 fix on support 10, wherein the extension line of the play liquid end of drain pipe 3 is through the removal route of optical cable. The water conveyed by the water conveying mechanism flows into the water storage tank 8 through the water outlet device, the tank body 4 is in a long strip shape, the water storage tank 8 is also in a long strip shape, the change area of the temperature of the water in the water storage tank 8 is located around the path passed by the optical cable and is a cylindrical area, so the change area is a preferential area for cooling, the scheme is provided with the shunt tubes 5, the shunt tubes 5 are arranged along the length direction of the water storage tank 8, the water output by the water conveying mechanism enters the shunt tubes 5, then the shunt tubes 5 are provided with a plurality of shunt ports which are connected with a plurality of liquid outlet pipes 3 through the shunt ports, finally the water flows into the water storage tank 8 through the liquid outlet pipes 3, in order to cool the surrounding area of the path passed by the optical cable, the water storage tank 8 in the scheme is provided with two shunt tubes 5, the two shunt tubes 5 are arranged at two sides of the water storage tank 8, then the liquid, make the water that shunt tubes 5 flowed out rush to the water of heating up to mix the cooling around the route of optical cable process, keep the invariant of temperature, wherein, its temperature is higher than the temperature of the water in the aqua storage tank 8 that will get into when the optical cable gets into aqua storage tank 8, the temperature around the route of the one end optical cable process that gets into at aqua storage tank 8 can be higher than the temperature of the 8 other ends of aqua storage tank like this, just need more water to mix and cool down in the one end that 8 optical cables got into at aqua storage tank like this, so the density that sets up drain pipe 3 of the one end that 8 optical cables got into in the aqua storage tank set up can increase, set the play liquid end of drain pipe 3 into the platykurtic simultaneously, make the water that flows out become fan-shaped distribution, can increase the area of radiation, the mixed effect is better.

Furthermore, the sleeve 13 is provided with a retaining ring 19 at both ends of the helical blade 16, and the retaining ring is used for sealing so that water is sealed between the two retaining rings 19.

Furthermore, a water conveying mechanism is arranged in the water conveying pipe 18 in the area of each water storage tank 8.

Further, one end of the sleeve 13, which is far away from the electromagnetic clutch 12, is rotatably connected to the rotating shaft 11 through a bearing 14. The purpose of setting up electromagnetic clutch 12 in this scheme is to realize carrying out regulation and control alone to the temperature of every aqua storage tank 8, because drive arrangement drives pivot 11 always and rotates, if the temperature of a certain aqua storage tank 8 does not need regulation and control temporarily, at this moment pivot 11 will make water get into the aqua storage tank 8 and cool down always with sleeve 13 keep being connected always, temperature will be out of control like this, so just need to connect the disconnection with the transmission of sleeve 13 with pivot 11 under this condition, so sleeve 13 in this scheme is connected with pivot 11 through electromagnetic clutch 12, make electromagnetic clutch 12 just realize the disconnection of the transmission of pivot 11 with sleeve 13 through the electrical disconnection when needing the disconnection, just so can carry out regulation and control alone to the temperature in every aqua storage tank 8.

Wherein, the side wall of each water storage tank 8 is provided with an overflow hole for controlling the water level in the water storage tank 8.

Further, a dynamic sealing device 17 is disposed between the two ends of the sleeve 13 and the rotating shaft 11, and the dynamic sealing device 17 is used for sealing the inside of the sleeve 13 so as to keep the electromagnetic clutch 12 operating in a dry environment.

Furthermore, the baffle 7 is provided with a threading hole 9, and the threading hole 9 is used for threading an optical cable.

Further, still include temperature detection module, all be provided with a temperature detection module in the aqua storage tank 8, temperature detection module protection a plurality of temperature sensor, it is a plurality of temperature sensor equipartition sets up, and is located the below of the removal route of optical cable. The temperature detection module is used for detecting the real-time temperature of each water storage tank 8, and the control system detects the water temperature of each water storage tank 8 through the temperature detection module, compares and judges the detected water temperature with the threshold water temperature set in each water storage tank 8, and stops water input when the water temperature is lower than the threshold range, namely the water input is stopped by only controlling the corresponding electromagnetic clutch 12 to be switched off; in addition, when the temperature of water is higher than a threshold value by a certain value, the rotating speed of the driving device can be controlled to achieve the control of water quantity input, the temperature is rapidly reduced through the increase of the water quantity, and the driving device 1 is connected with the rotating shaft 11 through the speed reducer 2 during normal work; the shunt pipe 5 in the water storage tank 8 with high water temperature and the water outlet 15 on the water delivery pipe 18 in the water storage tank 8 with low water temperature can be connected in parallel as the optimization of the scheme, and then the on-off is controlled by arranging the electromagnetic valve, for example, when the water temperature in 80 ℃ is too high, the electromagnetic valve can be controlled to introduce the water with 60 ℃ into the water storage tank 8 with 80 ℃ for rapid cooling.

The bottom of the tank body 4 is also provided with a circulating system, the circulating system cools the water in the tank body 4 and then circulates the water through the water storage tank 8 at 50 ℃ through the shunt pipe 5, the temperature of the water cooled by the circulating system is controlled to be 40 +/-5 ℃, so that the temperature of the water introduced into the water storage tank 8 is 40 +/-5 ℃, the cooling effect is achieved, and circulation is formed.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the present invention in any way. Those skilled in the art can make numerous possible variations and modifications to the described embodiments, or modify equivalent embodiments, without departing from the scope of the invention. Therefore, any modification, equivalent change and modification made to the above embodiments according to the technology of the present invention are within the protection scope of the present invention, unless the content of the technical solution of the present invention is departed from.

Claims (10)

1. The utility model provides a butterfly-shaped drop optical cable intelligence temperature control system which characterized in that: comprises a tank body (4), a plurality of baffles (7) are arranged in the tank body (4) to separate the interior of the tank body (4) into a plurality of water storage tanks (8), the plurality of water storage tanks (8) are used for containing water with different temperatures, the temperature of the water in the adjacent water storage tanks (8) is set to be step temperature, a temperature adjusting device (6) is arranged in the tank body (4), the temperature adjusting device (6) comprises a driving device (1), the output end of the driving device (1) is connected with a rotating shaft (11), the water conveying pipe (18) is arranged along the tank body (4), the water conveying pipe (18) penetrates through the plurality of baffles (7), the rotating shaft (11) is arranged in the water conveying pipe (18), a plurality of water conveying mechanisms are arranged on the rotating shaft (11), and each water conveying mechanism comprises an electromagnetic clutch (12), a sleeve (13) and a spiral blade (16), the inner ring of the electromagnetic clutch (12) is fixed on the rotating shaft (11), the sleeve (13) is sleeved on the rotating shaft (11), one end of the sleeve is fixedly connected with the outer ring of the electromagnetic clutch (12), the helical blade (16) is arranged on the outer side wall of the sleeve (13), and the outer edge of the helical blade (16) is attached to the inner wall of the water conveying pipe (18);

the utility model discloses a water storage tank, including raceway (18), raceway (18) and water outlet device, raceway (18) be located the lateral wall of helical blade (16) one end on seted up the water inlet, raceway (18) be located the lateral wall of helical blade (16) other end and seted up apopore (15), raceway (18) be connected with water outlet device through apopore (15), water outlet device sets up in aqua storage tank (8), pivot (11) rotate and drive helical blade (16) with the water in aqua storage tank (8) carry the other end of helical blade (16) through the water inlet and pass through apopore (15) and flow out, the water that flows out through apopore (15) flows into the aqua storage tank (8) that the temperature that sets up is higher than the water inlet temperature through water outlet device.

2. The intelligent temperature control system for the butterfly-shaped drop cable according to claim 1, wherein: and baffle rings (19) are arranged at two ends of the spiral blade (16) on the sleeve (13).

3. The intelligent temperature control system for the butterfly-shaped drop cable according to claim 1, wherein: a water conveying mechanism is arranged in the water conveying pipe (18) in the area of each water storage tank (8).

4. The intelligent temperature control system for the butterfly-shaped drop cable according to claim 1, wherein: one end of the sleeve (13) far away from the electromagnetic clutch (12) is rotatably connected with the rotating shaft (11) through a bearing (14).

5. The intelligent temperature control system for the butterfly-shaped drop cable according to claim 4, wherein: and a dynamic sealing device (17) is arranged between the two ends of the sleeve (13) and the rotating shaft (11).

6. The intelligent temperature control system for the butterfly-shaped drop cable according to claim 1, wherein: the baffle (7) is provided with a threading hole (9).

7. The intelligent temperature control system for the butterfly-shaped drop cable according to claim 1, wherein: go out the water installation include the rivers pipe, the one end of rivers pipe is passed through apopore (15) and raceway (18) intercommunication, the other end of rivers pipe is connected with shunt tubes (5), a plurality of diffluence spouts have been seted up along shunt tubes (5) axial on shunt tubes (5), shunt tubes (5) are connected with a plurality of drain pipes (3) through the diffluence spout.

8. The intelligent temperature control system for the butterfly-shaped drop cable according to claim 7, wherein: apopore (15) of seting up on the lateral wall of helical blade (16) one end be provided with two, two apopores (15) are equallyd divide and are connected with a rivers pipe respectively, wherein, shunt tubes (5) be provided with two, different rivers pipes are connected respectively in two shunt tubes (5), two shunt tubes (5) set up the both sides at aqua storage tank (8).

9. The intelligent temperature control system for the butterfly drop cable according to claim 8, wherein: all be provided with two supports (10) in aqua storage tank (8), drain pipe (3) fix on support (10), wherein the removal route of the extension line of the play liquid end of drain pipe (3) through the optical cable.

10. The intelligent temperature control system for the butterfly-shaped drop cable according to claim 1, wherein: still include the temperature detection module, all be provided with a temperature detection module in aqua storage tank (8), the temperature detection module protects a plurality of temperature sensor, and is a plurality of the temperature sensor equipartition sets up, and is located the below of the removal route of optical cable.

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