CN110802804A - Cold runner injection mold - Google Patents

Abstract

The invention discloses a cold runner injection mold which comprises an upper mold plate, a flow dividing assembly, an upper mold core assembly, a lower mold core assembly, an ejector pin assembly and a lower mold plate, wherein the upper mold core assembly and the lower mold core assembly can be covered to form a mold cavity, a main runner is arranged on the upper mold plate, the flow dividing assembly comprises a flow dividing frame, a flow dividing plate arranged on the flow dividing frame and a cold nozzle assembly, a first drainage channel, a flow dividing channel, a second drainage channel and a first waterway channel arranged around the flow dividing channel are arranged in the flow dividing plate, the main runner is communicated with the flow dividing channel through the first drainage channel, the cold nozzle assembly comprises a cold nozzle main body penetrating through the flow dividing frame and a cold nozzle arranged in the cold nozzle main body, one end of the cold nozzle is communicated with the flow dividing channel through the second drainage channel, the other end of the cold nozzle is communicated with the mold cavity, a second waterway channel is formed between the cold nozzle main body and the cold nozzle, and cold water is introduced into the first waterway channel and the second waterway channel to prevent silica gel from The heat solidifies in advance.

Description

Cold runner injection mold

Technical Field

The invention relates to the field of molds, in particular to a cold runner injection mold.

Background

In recent years, liquid silica gel is more and more widely used, and since silica gel is thermosetting plastic, namely cold liquid, is heated and cured, and cannot be liquefied after being cured, the traditional liquid silica gel is generally formed by extrusion, however, the liquid silica gel extrusion forming process has the following problems:

1. the operation procedures comprise operation procedures such as plasticizing, mixing, preforming and the like, the labor, material and energy are more, and the equipment investment and the equipment occupation space are increased due to the multiple procedures.

2. The size and quality of the product are affected by various variable factors and pollution in the processing process.

One of the methods for solving the above problems is to change the molding method of liquid silicone rubber to injection molding, and the molding process of liquid silicone rubber needs a cold runner technology, and the runner needs to be cold enough, however, the existing cold runner injection molding mold has the following problems:

1. the material is solidified due to heat generation in the runner caused by friction and shearing in the injection molding process, so that the temperature of the cold runner is controlled even if cold runner injection molding is used.

2. The heat insulation effect between the flow channel and the mold core is poor, the liquid silica gel is easy to vulcanize in the flow channel to block the cold nozzle, more waste materials are generated, and the cost is improved.

Disclosure of Invention

The invention aims to provide a cold runner injection mold, which aims to solve the technical problem that materials are heated and solidified in a runner in the injection molding process of the existing cold runner injection mold.

In order to achieve the purpose, the invention provides the following scheme:

the utility model provides a cold runner injection mold, is used for the silica gel shaping, cold runner injection mold includes cope match-plate pattern, reposition of redundant personnel subassembly, goes up mould benevolence subassembly, lower mould benevolence subassembly, thimble subassembly and lower bolster, reposition of redundant personnel subassembly go up mould benevolence subassembly lower mould benevolence subassembly thimble subassembly is followed the silica gel flow direction connects gradually the cope match-plate pattern with between the lower bolster, go up mould benevolence subassembly with lower mould benevolence subassembly can cover and close and form a die cavity, be equipped with the sprue on the cope match-plate pattern, the reposition of redundant personnel subassembly includes the reposition of redundant personnel frame, locates flow distribution plate and cold mouth subassembly on the reposition of redundant personnel frame, be equipped with first drainage way, subchannel, second drainage way in the flow distribution plate and enclose and locate the first waterway way of subchannel week side, the sprue passes through first drainage way with the subchannel intercommunication, cold mouth subassembly is including running through the cold mouth main part of reposition of redundant personnel frame and locating cold mouth in the, cold mouth one end is passed through the second drainage say with subchannel intercommunication, the other end with the die cavity intercommunication, cold mouth main part with form second waterway between the cold mouth, be equipped with first water inlet and first delivery port in the cold mouth main part, be equipped with inlet tube and outlet pipe on the reposition of redundant personnel frame, inlet tube one end is passed through first water inlet with second waterway intercommunication, the other end are used for with outside water route intercommunication, outlet pipe one end is passed through first delivery port with second waterway intercommunication, the other end are used for with outside water route intercommunication.

As an improvement mode, be equipped with the shunt tubes subassembly in the first waterway channel, the shunt tubes subassembly is including the first shunt tubes, second shunt tubes, third shunt tubes, fourth shunt tubes and the fifth shunt tubes that communicate in proper order, keep away from of first shunt tubes the one end of second shunt tubes is equipped with the second water inlet, keep away from of fifth shunt tubes the one end of fourth shunt tubes is equipped with the second delivery port.

As an improvement, the flow dividing plate includes a first flow dividing plate and a second flow dividing plate detachably connected to the first flow dividing plate, the flow dividing channel includes a first flow dividing channel provided on the first flow dividing plate and a second flow dividing channel provided on the second flow dividing plate, when the first flow dividing plate and the second flow dividing plate are fastened, the first flow dividing channel and the second flow dividing channel enclose to form the flow dividing channel, the first flow guiding channel is provided in the first flow dividing plate, the second flow guiding channel is provided in the second flow dividing plate and extends to the flow dividing frame, and the first waterway channel is provided between the first flow dividing plate and the second flow dividing plate.

As an improvement, the flow dividing assembly further includes a sealing ring disposed around the branch channel, and the sealing ring is disposed on the first flow dividing plate or the second flow dividing plate.

As an improvement, the cold nozzle is provided with a third drainage channel, the second drainage channel is communicated with the cavity through the third drainage channel, a groove is arranged around the outer peripheral side of the cold nozzle, and the second waterway channel is formed between the groove and the cold nozzle body.

As an improvement mode, the cold runner injection mold further comprises a first heat insulation plate and a second heat insulation plate, the first heat insulation plate is arranged between the shunting frame and the upper mold core assembly, the first heat insulation plate is provided with a plurality of mounting holes and a plurality of supporting cushion blocks in the mounting holes in a one-to-one correspondence mode, a perforation is formed in a penetrating mode of the first heat insulation plate, the cold nozzle assembly is far away from one end of the shunting frame penetrates through the perforation, and the second heat insulation plate is arranged on the outer peripheral side of the upper mold core assembly and the outer peripheral side of the lower mold core assembly.

As an improvement mode, a pouring gate is arranged on the upper die core component, one end of the pouring gate is communicated with the die cavity, one end, far away from the shunting frame, of the cold nozzle is arranged in the pouring gate and is communicated with the die cavity, and a heat insulation gasket is arranged at the position, in contact with the pouring gate, of the cold nozzle.

As an improvement mode, the orientation of cold mouth the draw-in groove has been seted up to the terminal surface of thermal-insulated gasket, the orientation of thermal-insulated gasket the protruding joint that is equipped with of terminal surface of cold mouth is in bellying in the draw-in groove, the thermal-insulated gasket passes through the bellying with the cooperation of draw-in groove with the cold mouth joint.

As an improvement, a mounting hole is formed in one end of the flow distribution frame facing the upper die core assembly, and the cold nozzle main body is mounted on an end face of the flow distribution frame facing the upper die core assembly through a screw.

As an improvement mode, go up the mould benevolence subassembly and include that the mould benevolence erects and establish go up the last mould benevolence on the mould benevolence frame, be provided with first heating element on the last mould benevolence frame, it is provided with the cavity to go up mould benevolence, the lower mould benevolence subassembly includes that lower mould benevolence erects and establishes lower mould benevolence on the lower mould benevolence frame, be equipped with second heating element on the lower mould benevolence frame, be provided with cavity down in the lower mould benevolence, lower cavity with it closes to go up the cavity lid and forms the die cavity, go up mould benevolence frame with.

According to the cold runner injection mold provided by the invention, the water channels are reasonably distributed, the first water channel surrounding the flow channel is arranged on the flow distribution plate, the second water channel is arranged on the cold nozzle assembly, and cold water is introduced into the first water channel and the second water channel to control the temperature of the flow channel and the cold nozzle, so that the advance solidification of silica gel due to heat generated by friction and shearing in the flow channel in the injection molding process is prevented.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

FIG. 1 is a schematic structural diagram of a cold runner injection mold provided by an embodiment of the present invention;

FIG. 2 is a view in the direction A of FIG. 1;

fig. 3 is a schematic structural diagram of a flow distribution plate provided in an embodiment of the present invention;

FIG. 4 is a schematic structural diagram of a first splitter plate according to an embodiment of the present invention;

fig. 5 is a schematic structural diagram of a second splitter plate according to an embodiment of the present invention;

FIG. 6 is a schematic structural view of a cold nozzle assembly provided by an embodiment of the present invention;

FIG. 7 is an assembly view of a cold nozzle assembly and a manifold block provided by an embodiment of the present invention;

FIG. 8 is a bottom view of a shunt shelf provided by embodiments of the present invention;

FIG. 9 is a top view of a first heat shield provided by an embodiment of the present invention;

FIG. 10 is a schematic structural diagram of a first heating assembly provided by an embodiment of the present invention;

fig. 11 is a schematic structural diagram of a second heating assembly according to an embodiment of the present invention.

The reference numbers illustrate:

a cold runner injection mold 100; a second water inlet 101; a second water outlet 102; a first splitter plate 103; a second splitter plate 104; a first branched flow path 105; a second sub-channel 106; a seal ring mounting groove 107;

an upper template 11; a main flow passage 111;

a flow diversion assembly 12; a shunt frame 121; an inlet pipe 1211; a water outlet pipe 1212; mounting holes 1213; a diverter plate 122; a bypass 1221; a first drainage channel 1222; a second drainage passage 1223; a first waterway passage 1224; a first shunt pipe 1225; a second shunt pipe 1226; a third shunt pipe 1227; a fourth shunt pipe 1228; a fifth shunt pipe 1229; a cold nozzle assembly 123; a cold nozzle body 1231; a cold nozzle 1232; a second waterway passage 1233; a first water inlet 1234; a first water outlet 1235; a third drainage channel 1236; a groove 1237; a clamp groove 1238; a seal ring 124;

an upper core assembly 13; a gate 131; an upper core frame 132; an upper mold core 133; a first heating assembly 134; an upper cavity 135;

a lower core assembly 14; a lower core frame 141; a lower mold core 142; a second heating element 143; a lower cavity 144;

a thimble assembly 15;

a lower die plate 16;

a first heat insulating board 17; mounting holes 171; a support pad 172; a perforation 173;

a second heat insulating board 18;

a heat insulating spacer 19; a boss 191;

a positioning device 20.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that all the directional indicators (such as up, down, left, right, front, and rear … …) in the embodiment of the present invention are only used to explain the relative position relationship between the components, the movement situation, etc. in a specific posture (as shown in the drawing), and if the specific posture is changed, the directional indicator is changed accordingly.

It will also be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present.

In addition, the descriptions related to "first", "second", etc. in the present invention are for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, technical solutions between various embodiments may be combined with each other, but must be realized by a person skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination should not be considered to exist, and is not within the protection scope of the present invention.

As shown in fig. 1 to 11, a cold runner injection mold 100 provided in an embodiment of the present invention is used for molding silica gel, the cold runner injection mold 100 includes an upper mold plate 11, a flow dividing assembly 12, an upper mold core assembly 13, a lower mold core assembly 14, an ejector pin assembly 15, and a lower mold plate 16, the flow dividing assembly 12, the upper mold core assembly 13, the lower mold core assembly 14, and the ejector pin assembly 15 are sequentially connected between the upper mold plate 11 and the lower mold plate 16 along a flow direction of the silica gel, the upper mold core assembly 13 and the lower mold core assembly 14 can be covered to form a mold cavity, a main runner 111 is disposed on the upper mold plate 11, the flow dividing assembly 12 includes a flow dividing frame 121, a flow dividing plate 122 disposed on the flow dividing frame 121, and a cold nozzle assembly 123, a sub-runner 1221, a first flow guiding passage 1222, a second flow guiding passage 1223, and a first passage surrounding the side of the sub-runner 1221 are disposed in the flow dividing plate 122, the cold nozzle assembly 123 includes a cold nozzle main body 1231 penetrating the diversion frame 121 and a cold nozzle 1232 arranged in the cold nozzle main body 1231, one end of the cold nozzle 1232 is communicated with the diversion channel 1221 through a second drainage channel 1223, the other end is communicated with the cavity, a second waterway channel 1233 is formed between the cold nozzle main body 1231 and the cold nozzle 1232, the cold nozzle main body 1231 is provided with a first water inlet 1234 and a first water outlet 1235, the diversion frame 121 is provided with a water inlet pipe 1211 and a water outlet pipe 1212, one end of the water inlet pipe 1211 is communicated with the second waterway channel 1233 through the first water inlet 1234, the other end is communicated with an external waterway, one end of the water outlet pipe 1212 is communicated with the second waterway channel 1233 through the first water outlet 1235, and the other end is communicated with the.

Silica gel enters the first drainage channel 1222 from the main channel 111, is shunted by the shunt channel 1221, enters the cold nozzle 1232 through the second drainage channel 1223, finally enters the cavity from the cold nozzle 1232 for solidification and molding, and after mold separation, the ejector pin assembly 15 ejects out molded silica gel, so that the silica gel can be taken away manually.

According to the cold runner injection mold 100 with the reasonable layout of the water channels, the first water channel 1224 surrounding the runner 1221 is arranged on the flow distribution plate 122, the second water channel 1233 is arranged on the cold nozzle assembly 123, cold water is introduced into the first water channel 1224 and the second water channel 1233 to control the temperature of the runner and the temperature of the cold nozzle 1232, and the silica gel is prevented from being solidified in advance due to heat generated by friction and shearing in the runner in the injection molding process.

Preferably, be equipped with the shunt tubes subassembly in first waterway 1224, the shunt tubes subassembly is including the first shunt tubes 1225 that communicates in proper order, second shunt tubes 1226, third shunt tubes 1227, fourth shunt tubes 1228 and fifth shunt tubes 1229, the one end that keeps away from second shunt tubes 1226 of first shunt tubes 1225 is equipped with second water inlet 101, the one end that keeps away from fourth shunt tubes 1228 of fifth shunt tubes 1229 is equipped with second delivery port 102, through directly set up the shunt tubes subassembly in first waterway 1224, logical cold water in the shunt tubes subassembly, need not lead to cold water in first waterway 1224, can reach the purpose of cooling flow distribution plate 122, rivers can not ooze simultaneously, the mould overall sealing nature is better.

Preferably, the diversion plate 122 includes a first diversion plate 103 and a second diversion plate 104, the first diversion plate 103 and the second diversion plate 104 are detachably connected, for example, by screws, the diversion channel 1221 includes a first diversion channel 105 provided on the first diversion plate 103 and a second diversion channel 106 provided on the second diversion plate, the first diversion channel 105 and the second diversion channel 106 have the same size, when the first diversion plate 103 and the second diversion plate 104 are fastened, the first diversion channel 105 and the second diversion channel 106 surround to form a diversion channel 1221, the first diversion channel 1222 is provided in the first diversion plate 103, the second diversion channel 1223 is provided in the second diversion plate 104 and extends to the diversion frame 121, the first waterway channel 1224 is provided between the first diversion plate 103 and the second diversion plate 104, that is, the first waterway channel 1224 may be provided at an end surface of the first diversion plate 103 facing the second diversion plate 104, or at an end surface of the second diversion plate 104 facing the first diversion plate 103, the other part of the flow dividing plate may be disposed on the end surface of the first flow dividing plate 103 facing the second flow dividing plate 104, and the other part of the flow dividing plate may be disposed on the end surface of the second flow dividing plate 104 facing the first flow dividing plate 103. The splitter plate 122 is divided into the first splitter plate 103 and the second splitter plate 104 for processing, so that the smoothness of the splitter passage 1221 can be ensured, the balance degree of the splitter passage 1221 can be ensured, and the screws can be directly removed when the sizing material of the splitter passage 1221 needs to be cleaned.

Furthermore, the flow dividing assembly 12 further includes a sealing ring 124, the first flow dividing plate 103 and the second flow dividing plate 104 are correspondingly provided with a sealing ring installation groove 107 surrounding the first flow dividing channel 105, the sealing ring 124 is installed in the sealing ring installation groove 107 of the first flow dividing channel 105 and the second flow dividing channel 106, and the sealing performance of the flow dividing channel 1221 is ensured by the arrangement of the sealing ring 124, so that the occurrence of the glue leakage phenomenon is avoided.

Preferably, the cold nozzle 1232 is provided with a third drainage channel 1236, the second drainage channel 1223 is communicated with the cavity through the third drainage channel 1236, the outer peripheral side of the cold nozzle 1232 is provided with a groove 1237 in a surrounding manner, a second waterway 1233 is formed between the groove 1237 and the cold nozzle main body 1231, and the structure is simple and practical.

Preferably, the cold runner injection mold 100 further includes a first heat insulation plate 17 and a second heat insulation plate 18, the first heat insulation plate 17 is disposed between the shunt frame 121 and the upper core assembly 13, the first heat insulation plate 17 is provided with a plurality of mounting holes 171 and a plurality of supporting pads 172 mounted in the mounting holes 171 in a one-to-one correspondence manner, the first heat insulation plate 17 is provided with a through hole 173 through which one end of the cold nozzle assembly 123 away from the shunt frame 121 passes, the second heat insulation plate 18 is mounted on an outer peripheral side of the upper core assembly 13 and the lower core assembly 14, the first heat insulation plate 17 and the second heat insulation plate 18 are disposed to insulate the upper core assembly 13 and the lower core assembly 14, so as to reduce heat dissipation generated by the upper core assembly 13 and the lower core assembly 14, thereby reducing temperature influence on the upper mold plate 11 and the shunt assembly 12, and, further, because the first heat insulation plate 17 has poor rigidity, in order to better protect the first heat insulation plate 17 and ensure rigidity and precision of, thereby, the rigid and precise support cushion block 172 is provided, and the flow dividing assembly 12 and the upper mold plate 11 are supported by the support cushion block 172.

Specifically, the first heat insulation plate 17 is mounted on an end surface of the shunt frame 121 facing the upper core assembly 13, and the support pad 172 is fixed on the shunt frame 121 by screws.

Preferably, the upper mold core assembly 13 is provided with a gate 131, one end of the gate 131 is communicated with the cavity, one end of the cold nozzle 1232, which is far away from the split frame 121, is arranged in the gate 131 and is communicated with the cavity, the position of the cold nozzle 1232, which is in contact with the gate 131, is provided with a heat insulation gasket 19, and the position of the cold nozzle 1232, which is in contact with the gate 131, is provided with the heat insulation gasket 19, so that the influence of the temperature of the upper mold core assembly 13 and the lower mold core assembly 14 on the cold nozzle 1232 is reduced, and the flowability of the silica gel.

Furthermore, the end surface of the cold nozzle 1232 facing the heat insulation gasket 19 is provided with a clamping groove 1238, the end surface of the heat insulation gasket 19 facing the cold nozzle 1232 is convexly provided with a protrusion 191 clamped in the clamping groove 1238, and the heat insulation gasket 19 is clamped with the cold nozzle 1232 through the matching of the protrusion 191 and the clamping groove 1238, so that the connection mode is simple and reliable, and the assembly and disassembly are convenient.

Preferably, the shunt frame 121 has a mounting hole 1213 towards one end of the upper mold core assembly 13, the cold nozzle main body 1231 is mounted on the end surface of the shunt frame 121 towards the upper mold core assembly 13 through a screw, that is, the cold nozzle assembly 123 is mounted on the shunt frame 121 in an inverted manner, after the cold nozzle assembly 123 is mounted, the shunt assembly 12 is mounted on the upper mold core assembly 13, so that the design is adopted, the shunt assembly 12 and the upper mold plate 11 do not need to be dismounted, the cold nozzle assembly 123 can be dismounted, the mounting and dismounting are convenient, meanwhile, the cold nozzle assembly 123 can be designed to have the same length under the condition that the height of the upper mold core assembly 13 is not far different in design, and the standardization is easy.

Preferably, the upper core assembly 13 includes an upper core frame 132 and an upper core 133 disposed on the upper core frame 132, the upper core frame 132 is provided with a first heating assembly 134, the upper core 133 is provided with an upper cavity 135, the gate 131 is disposed on the upper core frame 132 and extends into the upper core 133 to communicate with the upper cavity 135, the lower core assembly 14 includes a lower core frame 141 and a lower core 142 disposed on the lower core frame 141, the lower core frame 141 is provided with a second heating assembly 143, a lower cavity 144 is disposed in the lower core 142, the lower cavity 144 and the upper cavity 135 cover to form a cavity, and the positioning device 20 is disposed between the upper core frame 132 and the lower core frame 141.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention, and all modifications and equivalents of the present invention, which are made by the contents of the present specification and the accompanying drawings, or directly/indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (10)

1. Cold runner injection mold for the silica gel shaping, cold runner injection mold includes cope match-plate pattern, reposition of redundant personnel subassembly, goes up mould benevolence subassembly, lower mould benevolence subassembly, thimble subassembly and lower bolster, the reposition of redundant personnel subassembly go up mould benevolence subassembly lower mould benevolence subassembly thimble subassembly is followed the silica gel flow direction connects gradually the cope match-plate pattern with between the lower bolster, go up mould benevolence subassembly with lower mould benevolence subassembly can cover and close and form a die cavity, a serial communication port, be equipped with the sprue on the cope match-plate pattern, the reposition of redundant personnel subassembly includes the reposition of redundant personnel frame, locates last flow distribution plate and the cold mouth subassembly of reposition of redundant personnel frame, be equipped with first drainage way, subchannel way, second drainage way in the flow distribution plate and enclose and locate branch runner week side's first waterway way, the sprue passes through first drainage way with the subchannel intercommunication, the cold mouth subassembly is including running through the cold mouth main part of reposition of redundant personnel frame and locating cold mouth in the cold The utility model discloses a cold mouth, including cold mouth, inlet tube, outlet pipe, first water inlet, second water channel, first delivery port, second water channel, second delivery port, first water inlet and first delivery port, the die cavity intercommunication is in the cold mouth, cold mouth one end is passed through the second drainage way with subchannel intercommunication, the other end with the die cavity intercommunication, the cold mouth main part with form second water channel between the cold mouth, be equipped with first water inlet and first delivery port in the cold mouth main part, be equipped with inlet tube and outlet pipe on the reposition of redundant personnel frame, inlet tube one end is passed through first water inlet with second water channel intercommunication, the other end are used.

2. The cold runner injection mold of claim 1, wherein a shunt tube assembly is arranged in the first waterway channel, the shunt tube assembly comprises a first shunt tube, a second shunt tube, a third shunt tube, a fourth shunt tube and a fifth shunt tube which are sequentially communicated, a second water inlet is arranged at one end of the first shunt tube, which is far away from the second shunt tube, and a second water outlet is arranged at one end of the fifth shunt tube, which is far away from the fourth shunt tube.

3. The cold runner injection mold of claim 1, wherein the splitter plate comprises a first splitter plate and a second splitter plate detachably connected to the first splitter plate, the splitter plate comprises a first splitter channel provided on the first splitter plate and a second splitter channel provided on the second splitter plate, when the first splitter plate and the second splitter plate are fastened, the first splitter channel and the second splitter channel enclose to form the splitter channel, the first flow guide is provided in the first splitter plate, the second flow guide is provided in the second splitter plate and extends to the splitter frame, and the first waterway channel is provided between the first splitter plate and the second splitter plate.

4. The cold runner injection mold of claim 3, wherein the manifold assembly further comprises a seal ring disposed around the manifold, the seal ring being disposed on the first manifold plate or the second manifold plate.

5. The cold runner injection mold according to claim 1, wherein the cold nozzle is provided with a third flow guide, the second flow guide is communicated with the cavity through the third flow guide, a groove is circumferentially arranged on the outer peripheral side of the cold nozzle, and the second water channel is formed between the groove and the cold nozzle body.

6. The cold runner injection mold of claim 1, further comprising a first heat insulation plate and a second heat insulation plate, wherein the first heat insulation plate is disposed between the split frame and the upper mold core assembly, the first heat insulation plate is provided with a plurality of mounting holes and a plurality of supporting cushion blocks which are correspondingly mounted in the mounting holes one by one, the first heat insulation plate is provided with through holes in a penetrating manner, one end of the cold nozzle assembly, which is far away from the split frame, penetrates through the through holes, and the second heat insulation plate is mounted on the outer peripheral sides of the upper mold core assembly and the lower mold core assembly.

7. The cold runner injection mold of claim 1, wherein a gate is disposed on the upper mold core assembly, one end of the gate is communicated with the cavity, one end of the cold nozzle away from the split frame is disposed in the gate and communicated with the cavity, and a heat insulation gasket is disposed at a contact position of the cold nozzle and the gate.

8. The cold runner injection mold of claim 7, wherein a clamping groove is formed in an end surface of the cold nozzle facing the heat insulating gasket, a protruding portion clamped in the clamping groove is convexly arranged on an end surface of the heat insulating gasket facing the cold nozzle, and the heat insulating gasket is clamped with the cold nozzle through matching of the protruding portion and the clamping groove.

9. The cold runner injection mold of claim 1, wherein an end of the manifold facing the upper core assembly is provided with a mounting hole, and the cold nozzle body is mounted on an end surface of the manifold facing the upper core assembly by screws.

10. The cold runner injection mold according to claim 1, wherein the upper mold core assembly comprises an upper mold core frame and an upper mold core arranged on the upper mold core frame, the upper mold core frame is provided with a first heating assembly, the upper mold core is provided with an upper cavity, the lower mold core assembly comprises a lower mold core frame and a lower mold core arranged on the lower mold core frame, the lower mold core frame is provided with a second heating assembly, the lower mold core is provided with a lower cavity, the lower cavity and the upper cavity cover to form the mold cavity, and a positioning device is arranged between the upper mold core frame and the lower mold core frame.

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