CN113929279B - Glass spiral pipe blowing system - Google Patents

Abstract

The invention belongs to the field of glass processing, and relates to a glass spiral tube blowing system which comprises a box body, wherein a mounting platform is fixedly arranged in the box body far away from the bottom of the box body, a supporting base is fixedly arranged on one side of the bottom of the box body, a rotating supporting ring is arranged on the supporting base in a sliding manner, a mold box is fixedly arranged on the rotating supporting ring, a first rail shell is fixedly arranged on one side, facing the box body, of the mounting platform, a mounting sliding block is fixedly arranged in the first rail shell in a sliding manner, a telescopic base is fixedly arranged in one side, facing the lower end face of the box body, of the mounting sliding block, a telescopic shell is fixedly arranged on the telescopic base, a telescopic rod is fixedly arranged in the telescopic shell in a sliding manner, a second rail shell is fixedly arranged on two side walls of the box body, and a sliding block is fixedly arranged on one side, far away from the supporting base, of the lower end face of the box body. Can effectively solve the problem that the pipe diameter of the glass spiral pipe cannot be kept consistent in the longitudinal direction in the blowing process.

Description

Glass spiral pipe blowing system

Technical Field

The invention belongs to the field of glass processing, and particularly relates to a glass spiral tube blowing system.

Background

Glass tubes are a type of non-metallic tubes, and are glass with sodium oxide, boron oxide, and silicon dioxide as basic components. Its good performance has been widely accepted in all world, compared with common glass, it has no toxic side effect, its mechanical property, thermal stability, water-resistance, alkali-resistance and acid-resistance properties are greatly raised, in the course of making glass tube it adopts blow-moulding process, also called hollow blow-moulding process, so that it is a plastic processing method with quick development.

Common glass tube blowing industry is including being artifical blow molding, in the work of artifical blowing, need artifical handheld blowing pipe dip in plastics, stretch plastics in the in-process of blowing, mould the type to the glass tube through the air current of blowing simultaneously, because of the air current is unstable relatively in the manual blowing process, and ordinary glass tube goods often need the manual work frequently to change between blowing and reheat two steps and make a round trip operation extravagant manpower when the preparation, often can't make glass tube inner wall keep unified wall thickness in the vertical direction in the glass tube preparation process, this makes the glass tube internal diameter unable to keep unanimously, therefore have the improvement necessity.

Disclosure of Invention

The invention aims at solving the problems in the prior art and provides a glass spiral pipe blowing system which can effectively solve the problem that the pipe diameter of a glass spiral pipe cannot be kept consistent in the longitudinal direction in the blowing process.

The aim of the invention can be achieved by the following technical scheme: the utility model provides a glass spiral pipe blowing system, includes the box, keep away from the bottom half in the box and set firmly mounting platform, bottom half one side has set firmly the support base, it has rotated the support ring to slide on the support base, it has set firmly the mould case to rotate on the support ring, one side of facing towards the box in the mounting platform has set firmly first track casing, it has set firmly the installation slider to slide in the first track casing, the installation slider faces towards the lower terminal surface of box one side in set firmly flexible base, set firmly flexible casing on the flexible base, the telescopic link has been slided in the flexible casing, set firmly the second track casing on the both sides wall in the box, it has set firmly the sliding block to slide in the second track casing, keep away from the smelting furnace on the terminal surface under in the box one side of support base.

Preferably, the first track shell is a downward-facing transverse straight rail, the rotary supporting ring is a square box, the smelting furnace is cylindrical, the second track shell is a downward-facing transverse straight rail, and the second track shell is symmetrically arranged at two sides of the box.

Preferably, the output of telescopic link has set firmly the connecting block, connecting block lower extreme sliding connection has the swivel becket, the terminal surface has set firmly the installation piece under the swivel becket, the installation piece is interior to be equipped with the axis of rotation, the axis of rotation has set firmly the sleeve outward, telescopic one side of keeping away from the axis of rotation has set firmly the pole of blowing, be equipped with the gas blow pipe in the pole of blowing, the gas blow pipe passes the connecting block and stretches out in the telescopic link and link to each other with the pump machine, the pump machine is located the connecting block up end.

Preferably, the electric telescopic shell is fixedly arranged on the sliding block, the electric telescopic rod is arranged in the electric telescopic shell in a sliding mode, the fastening block is fixedly arranged at the output end of the electric telescopic rod, the sliding shell is fixedly arranged on one side wall, adjacent to the second track shell, of the box body, the sliding rod is arranged in the sliding shell in a sliding mode, the connecting rod is fixedly arranged at the output end of the sliding rod, a sliding groove is fixedly formed in one side, close to the upper side, of the connecting rod, a feeler lever is arranged in the sliding groove in a sliding mode, the feeler lever is connected with the sliding groove through a spring, and a cover plate is fixedly arranged at one end of the connecting rod.

Preferably, a setting barrel is fixedly arranged in the smelting furnace, an arc barrel is fixedly arranged on the inner lower surface of the setting barrel, heating plates are arranged on the two sides of the inner lower surface of the smelting furnace, a hot melting motor is arranged outside the smelting furnace, and the smelting furnace is connected with a cover plate.

Preferably, the die box is internally fixedly provided with a die plate mounting groove, a first hydraulic shell is fixedly arranged in the side end face of the die plate mounting groove, a first hydraulic rod is slidably arranged in the first hydraulic shell, the output end of the first hydraulic rod is fixedly provided with a connecting plate, a circular tube die plate is fixedly arranged on the connecting plate, the circular tube die plate slides in the die plate mounting groove, the upper surface of the die plate mounting groove is fixedly provided with a die plate connecting rod, one side of the die plate connecting rod is fixedly provided with a sliding mounting block, the sliding mounting block is slidably provided with a trimming shell, the side wall of the lower end in the trimming shell is fixedly provided with a lower trimming cylinder, the upper end of the lower trimming cylinder is fixedly provided with an elastic clamping block, the lower trimming cylinder is slidably provided with an upper trimming cylinder, the lower trimming cylinder and the trimming shell are internally provided with a limiting groove, a second spring is elastically connected, the upper trimming cylinder slides in the limiting groove, the trimming shell is elastically connected with the template connecting rod through a third spring, a second die groove is fixedly arranged at the upper end of the template connecting rod, a second hydraulic shell is fixedly arranged on the inner side wall of the second die groove, a second hydraulic rod is arranged in the second hydraulic shell in a sliding mode, a die connecting block is fixedly arranged at the output end of the second hydraulic rod, a second die is fixedly arranged on the die connecting block, a heating motor is arranged in the second die, two groups of components required by the die groove to the second die and the elastic connection are symmetrically arranged in the die box, a pump machine placing box is fixedly arranged at the center of the upper surface of the supporting base, an air pipe groove is fixedly arranged at one side of the pump machine placing box, an air pump is arranged in the pump machine placing box, the output end of the air pump is communicated with an output pipe of the pump machine, the output pipe of the pump machine is communicated with two gaps of the round pipe template through the air pipe groove, the input end of the air pump penetrates through the supporting base and is communicated with the outside.

Compared with the prior art, the invention has the following advantages:

1. the glass tube can be initially extruded to shape the softened glass prior to blow molding the spiral glass tube and the glass is continuously heated during the process to allow for efficient filling of the mold subsequently.

2. After the preliminary shaping and blow molding are finished, the redundant parts generated by extruding the outer side of the spiral glass tube by the die can be scraped by the trimming part.

3. The internal air pressure of the glass tank is kept stable by two-way air blowing at two sides, and the internal diameter of the glass tube is basically kept consistent by matching with external rotation.

Drawings

Fig. 1 is a perspective view of the present invention.

Fig. 2 is a front view of the present invention.

Fig. 3 is a side view of the present invention.

Fig. 4 is a sectional view taken along the direction A-A in fig. 3.

Fig. 5 is a sectional view in the direction B-B of fig. 4.

Fig. 6 is a sectional view taken along the direction C-C in fig. 4.

Fig. 7 is an enlarged view of D in fig. 4.

Fig. 8 is an enlarged view at F in fig. 6.

Fig. 9 is a view of the glass tube after preliminary press.

Fig. 10 is a finished product diagram.

In the drawing, a box body 10, a mounting platform 11, a support base 12, a rotation support ring 13, a first rail housing 14, a mounting slide block 15, a telescopic base 16, a telescopic housing 17, a telescopic rod 18, a second rail housing 19, a sliding block 20, a smelting furnace 21, a sliding housing 22, a sliding rod 23, a connecting block 24, a rotation ring 25, a mounting block 26, a rotation shaft 27, a sleeve 28, a blowing rod 29, a blowing pipe 30, a sliding cylinder 31, a sliding connection gasket 32, a pump 33, an electric telescopic housing 34, an electric telescopic rod 35, a fastening block 36, a connecting rod 37, a chute 38, a feeler rod 39, a spring 40, a cover plate 41, a mounting cylinder 42, an arc-shaped barrel 43, a heating plate 44, a hot melt motor 45, a template mounting groove 46, a first hydraulic housing 47, a first hydraulic rod 48, a connecting plate 49, a circular tube template 50, a template connecting rod 51, a sliding mounting block 52, a trimming housing 53, a lower trimming cylinder 54, an upper trimming cylinder 55, an elastic clamping block 56, a limiting groove 57, a second spring 58, a second mold groove 59, a second hydraulic housing 60, a second hydraulic rod 61, a second hydraulic rod 62, a mold 64, a third mold 64, a spiral tube 64, a heating cylinder 67, a spiral tube 70, a finished product pump box 71, a spiral tube box 71, a pump 71, a spiral tube 65, a finished product pump housing 65, a heating cylinder 67, a spiral tube 71, a pump housing 64, a spiral tube 66, a pump housing 65, and a finished product tanks 71.

Detailed Description

The following are specific embodiments of the present invention and the technical solutions of the present invention will be further described with reference to the accompanying drawings, but the present invention is not limited to these embodiments.

As shown in fig. 1-10, a glass spiral tube blowing system comprises a box body 10, wherein an installation platform 11 is fixedly arranged in the box body 10 far away from the bottom of the box body 10, a supporting base 12 is fixedly arranged on one side of the bottom of the box body 10, a rotating supporting ring 13 is slidably arranged on the supporting base 12, a mold box 65 is fixedly arranged on the rotating supporting ring 13, a first rail shell 14 is fixedly arranged on one side, facing towards the box body 10, of the installation platform 11, an installation sliding block 15 is slidably arranged in the first rail shell 14, a telescopic base 16 is fixedly arranged on one side, facing towards the lower end face of the box body 10, of the installation sliding block 15, a telescopic shell 17 is fixedly arranged on the telescopic base 16, a telescopic rod 18 is slidably arranged in the telescopic shell 17, a second rail shell 19 is fixedly arranged on two side walls in the box body 10, a sliding block 20 is slidably arranged in the second rail shell 19, and a smelting furnace 21 is fixedly arranged on one side, facing away from the supporting base 12, of the lower end face in the box body 10.

Further, the first rail housing 14 is a downward facing horizontal straight rail, the rotary supporting ring 13 is a square box, the smelting furnace 21 is cylindrical, and the second rail housing 19 is a horizontal straight rail facing both sides and symmetrically arranged at both sides of the box 10.

Further, the output end of the telescopic rod 18 is fixedly provided with a connecting block 24, the lower end of the connecting block 24 is slidably connected with a rotating ring 25, the lower end face of the rotating ring 25 is fixedly provided with a mounting block 26, a rotating shaft 27 is slidably arranged in the mounting block 26, a sleeve 28 is fixedly arranged outside the rotating shaft 27, one side, far away from the rotating shaft 27, of the sleeve 28 is fixedly provided with a blowing rod 29, a blowing pipe 30 is arranged in the blowing rod 29, the blowing pipe 30 penetrates through the connecting block 24 and stretches out of the telescopic rod 18 to be connected with a pump 33, and the pump 33 is arranged on the upper end face of the connecting block 24.

Further, an electric telescopic housing 34 is fixedly arranged on the sliding block 20, an electric telescopic rod 35 is slidably arranged in the electric telescopic housing 34, a fastening block 36 is fixedly arranged at the output end of the electric telescopic rod 35, a sliding housing 22 is fixedly arranged on one side wall adjacent to the second track housing 19 in the box 10, a sliding rod 23 is slidably arranged in the sliding housing 22, a connecting rod 37 is fixedly arranged at the output end of the sliding rod 23, a sliding groove 38 is fixedly arranged on one side, close to the upper side, of the connecting rod 37, a trolley 39 is slidably arranged in the sliding groove 38, the trolley 39 is connected with the sliding groove 38 through a spring 40, and a cover plate 41 is fixedly arranged at one end of the connecting rod 37.

Further, a setting cylinder 42 is fixedly arranged in the smelting furnace 21, an arc-shaped barrel 43 is fixedly arranged on the inner lower surface of the setting cylinder 42, heating plates 44 are arranged on the two sides of the inner lower surface of the smelting furnace 21, a hot melting motor 45 is arranged outside the smelting furnace 21, and the smelting furnace 21 is connected with the cover plate 41.

Further, a template setting groove 46 is fixedly arranged in the mold box 65, a first hydraulic shell 47 is fixedly arranged in the side end face of the template setting groove 46, a first hydraulic rod 48 is arranged in the first hydraulic shell 47 in a sliding manner, a connecting plate 49 is fixedly arranged at the output end of the first hydraulic rod 48, a circular tube template 50 is fixedly arranged on the connecting plate 49, the circular tube template 50 slides in the template setting groove 46, a template connecting rod 51 is fixedly arranged on the upper surface of the template setting groove 46, a sliding setting block 52 is fixedly arranged on one side of the template connecting rod 51, a trimming shell 53 is slidingly arranged on the sliding setting block 52, a lower trimming cylinder 54 is fixedly arranged on the side wall of the lower end in the trimming shell 53, an elastic clamping block 56 is fixedly arranged on the upper end of the lower trimming cylinder 54, an upper trimming cylinder 55 is slidingly arranged on the lower trimming cylinder 54 in the trimming shell 53, a limiting groove 57 is arranged at the upper end of the lower trimming cylinder 54, a second spring 58 is elastically connected between the upper trimming cylinder 55 and the trimming shell 53, the upper trimming cylinder 55 slides in the limit groove 57, a third spring 66 is elastically connected between the trimming shell 53 and the template connecting rod 51, a second mould groove 59 is fixedly arranged at the upper end of the template connecting rod 51, a second hydraulic shell 60 is fixedly arranged on the inner side wall of the second mould groove 59, a second hydraulic rod 61 is slidingly arranged in the second hydraulic shell 60, a mould connecting block 62 is fixedly arranged at the output end of the second hydraulic rod 61, a second mould 64 is fixedly arranged on the mould connecting block 62, a heating motor 63 is arranged in the second mould 64, two groups of parts required by the template arranging groove 46 to the second mould 64 and elastic connection are symmetrically arranged in the mould box 65, a pump arranging box 67 is fixedly arranged at the center of the upper surface of the supporting base 12, an air pipe groove 68 is fixedly arranged at one side of the pump arranging box 67, an air pump 69 is arranged in the pump arranging box 67, the output end of the air pump 69 is communicated with the pump output pipe 70, the pump output pipe 70 is communicated with the inside of the two gaps of the circular tube template 50 through the air pipe groove 68, and the input end of the air pump 69 is communicated with the outside through the supporting base 12.

Working principle:

the installation slider 15 drives the blowing rod 29 to move towards the position of the moving smelting furnace 21, the sliding cylinder 31 is contacted with the feeler lever 39 in the moving process to enable the feeler lever 39 to move inwards to achieve a buffer effect, the sliding cylinder 31 continues to move the sliding rod 23, the sliding rod 23 moves to drive the cover plate 41 to move to open the smelting furnace 21, the telescopic rod 18 stretches downwards after the smelting furnace 21 is opened to enable the blowing rod 29 to be inserted into softened glass in the smelting furnace 21 and enable one end of the blowing rod 29 to clamp the softened glass through rotation of the rotating ring 25, then the blowing rod 29 moves out, the installation slider 15 moves between the support base 12 and the smelting furnace 21, then the sliding block 20 moves to the position of the blowing rod 29, then the electric telescopic rod 35 stretches to enable the fastening block 36 to be contacted with the softened glass, at the moment, the fastening block 36 is positioned at a port of the blowing rod 29, the rotating ring 25 rotates when the fastening block 36 is contacted with the glass, the fastening block 36 continues to stretch slowly, and the port of the glass and the blowing rod 29 is sealed firmly.

After the sealing is completed, the electric telescopic rod 35 is retracted, the sleeve 28 rotates by a small amplitude around the rotating shaft 27, the blowing rod 29 is driven to swing left and right, the softened glass stretches downwards along with gravity, and the mounting sliding block 15 moves to be right above the supporting base 12 after stretching and stretches into the die box 65.

When the elongated glass stretches into the second mold groove 59, the second hydraulic rod 61 stretches to drive the second mold 64 to move to two sides to bend the glass to form a primary blank, the heating motor 63 in the second mold 64 continuously heats the glass during the primary bending to keep the glass in a softened state, one end of the bent glass enters the trimming shell 53, the rotating ring 25 drives the glass to rotate to enable the glass to move downwards in a channel of the upper trimming cylinder 55, burrs on the glass are scraped in the downward moving process, and the upper trimming cylinder 55 is limited by the trimming shell 53 at the moment and does not move, and after the glass completely passes through the trimming shell 53, the port of the blowing rod 29 is pressed downwards to enable the elastic clamping block 56 to be pressed downwards to enable the upper trimming cylinder 55 to slide into the limiting groove 57.

The bent glass enters the template setting groove 46, the first hydraulic rod 48 drives the circular tube template 50 to cover the glass, the pump 33 starts blowing like the glass, the air pump 69 starts blowing the glass into the circular tube template 50 at the same time when the glass expands, the supporting ring 13 rotates to drive the elastic clamping block 56 to rotate when the air is blown, the rotating ring 25 rotates at the same speed, the glass is subjected to centrifugal force when being expanded by internal air pressure, and the inner wall of the glass starts to expand outwards uniformly.

The formed bent glass tube moves up through the lower trimming cylinder 54, and the rotating ring 25 rotates to make the lower trimming cylinder 54 trim burrs of the glass tube at the edges of the mold, and since the upper trimming cylinder 55 is slid into the limiting groove 57, the two trimming housings 53 are formed to have a diameter larger than that of the upper trimming cylinder 55, so that the trimming housings 53 can be extended.

The foregoing description is only illustrative of the present invention and is not intended to limit the scope of the invention, and all equivalent structures or equivalent processes using the descriptions and the drawings of the present invention or directly or indirectly applied to other related technical fields are included in the scope of the invention.

Claims (4)

1. The utility model provides a glass spiral pipe blowing system, includes box (10), its characterized in that, keep away from box (10) bottom in box (10) and set firmly mounting platform (11), support base (12) have been set firmly to box (10) bottom one side, support base (12) are gone up to slide and are equipped with rotation support ring (13), have set firmly mould case (65) on rotation support ring (13), one side of facing box (10) in mounting platform (11) has set firmly first track casing (14), the interior sliding block (15) that is equipped with of first track casing (14), set firmly flexible base (16) in one side of terminal surface under the mounting sliding block (15) facing box (10), flexible casing (17) have been set firmly on flexible base (16), flexible casing (17) are gone up to slide and are equipped with telescopic link (18), second track casing (19) have been set firmly on the both sides wall in box (10), second track casing (19) are gone up to slide and are equipped with sliding block (20), one side of keeping away from smelting furnace (21) under the terminal surface (10); the telescopic device is characterized in that a connecting block (24) is fixedly arranged at the output end of the telescopic rod (18), a rotating ring (25) is slidably connected to the lower end of the connecting block (24), a mounting block (26) is fixedly arranged on the lower end face of the rotating ring (25), a rotating shaft (27) is slidably arranged in the mounting block (26), a sleeve (28) is fixedly arranged outside the rotating shaft (27), a blowing rod (29) is fixedly arranged on one side, far away from the rotating shaft (27), of the sleeve (28), a blowing pipe (30) is arranged in the blowing rod (29), the blowing pipe (30) penetrates through the connecting block (24) and extends out of the telescopic rod (18) to be connected with a pump (33), and the pump (33) is arranged on the upper end face of the connecting block (24). The die box (65) is internally fixedly provided with a die plate accommodating groove (46), the side end face of the die plate accommodating groove (46) is internally fixedly provided with a first hydraulic shell (47), the inner side of the first hydraulic shell (47) is internally provided with a first hydraulic rod (48), the output end of the first hydraulic rod (48) is fixedly provided with a connecting plate (49), the connecting plate (49) is fixedly provided with a circular tube die plate (50), the circular tube die plate (50) slides in the die plate accommodating groove (46), the upper surface of the die plate accommodating groove (46) is fixedly provided with a die plate connecting rod (51), one side of the die plate connecting rod (51) is fixedly provided with a sliding accommodating block (52), the sliding accommodating block (52) is upwards provided with a trimming shell (53), the side wall of the lower end of the inner side of the trimming shell (53) is fixedly provided with a lower trimming cylinder (54), the upper end of the lower trimming cylinder (54) is fixedly provided with an elastic clamping block (56), the lower trimming cylinder (54) is slidably provided with an upper trimming cylinder (55), the lower end of the trimming cylinder (54) in the trimming shell (53) is internally provided with a sliding limiting groove (55), the upper trimming cylinder (55) is connected with the upper trimming shell (55), the edge trimming shell (53) is elastically connected with a third spring (66) between the die plate connecting rod (51), a second die groove (59) is fixedly arranged at the upper end of the die plate connecting rod (51), a second hydraulic shell (60) is fixedly arranged on the inner side wall of the second die groove (59), a second hydraulic rod (61) is slid in the second hydraulic shell (60), a die connecting block (62) is fixedly arranged at the output end of the second hydraulic rod (61), a second die (64) is fixedly arranged on the die connecting block (62), a heating motor (63) is arranged in the second die (64), two groups of parts required for elastic connection are symmetrically arranged in the die box (65) from the die plate placing groove (46) to the second die (64), a pump placing box (67) is fixedly arranged at the center of the upper surface of the supporting base (12), an air pipe groove (68) is fixedly arranged on one side of the pump placing box (67), an air pump (69) is arranged in the pump placing box (67), an output end of the air pump (69) and an air pipe (70) are fixedly connected with the pump (70), and the output end of the air pipe (70) and the air pipe (70) are communicated with the air pipe (70) and the air pipe (70) penetrates through the die plate (12) and the die plate (50).

2. A spiral tube glass blowing system according to claim 1, wherein: the first rail shell (14) is a downward-facing transverse straight rail, the rotary supporting ring (13) is a square box body, the smelting furnace (21) is cylindrical, the second rail shell (19) is a transverse straight rail facing to two sides, and the two sides of the box body (10) are symmetrically arranged.

3. A spiral tube glass blowing system according to claim 1, wherein: the utility model discloses a telescopic trolley is characterized in that an electric telescopic shell (34) is fixedly arranged on a sliding block (20), an electric telescopic rod (35) is arranged in the electric telescopic shell (34) in a sliding mode, a fastening block (36) is fixedly arranged at the output end of the electric telescopic rod (35), a sliding shell (22) is fixedly arranged on one side wall adjacent to a second track shell (19) in a box body (10), a sliding rod (23) is arranged in the sliding shell (22) in a sliding mode, a connecting rod (37) is fixedly arranged at the output end of the sliding rod (23), a sliding groove (38) is fixedly arranged on one side, close to the upper side, of the connecting rod (37), a trolley (39) is arranged in the sliding groove (38) in a sliding mode, the trolley (39) is connected with the sliding groove (38) through a spring (40), and a cover plate (41) is fixedly arranged at one end of the connecting rod (37).

4. A spiral tube glass blowing system according to claim 1, wherein: the utility model discloses a smelting furnace, including smelting furnace (21), arc barrel (43) have been set firmly in smelting furnace (21), arc barrel (43) have been set firmly on the lower surface in setting up barrel (42), both sides are equipped with hot plate (44) on the lower surface in smelting furnace (21), smelting furnace (21) are equipped with hot melt motor (45) outward, link to each other with apron (41) on smelting furnace (21).