CN111716632A - Special full-automatic multiple operation processing all-in-one of coil casing - Google Patents

Abstract

The invention discloses a special full-automatic multi-process machining all-in-one machine for a coil shell, which comprises a U-shaped supporting plate, wherein the upper left side of a bottom plate of the U-shaped supporting plate is connected with an electric sliding mechanism, the upper side of the electric sliding mechanism is connected with a jacking mechanism in an equidistant mode from left to right, the upper side of the jacking mechanism is connected with a concave die body, a lifting plate is horizontally arranged right above the concave die body, the lower end surface of the lifting plate is fixedly connected with convex die bodies in an equidistant mode from left to right, and an injection molding mechanism is fixedly arranged on the lifting plate above the position of each. According to the invention, the first electric telescopic rod is started to extend downwards, so that the lifting plate drives the convex die body to be correspondingly embedded into the concave die body, and when the port of the concave die body is closed by the lifting plate, the first proximity inductive switch is triggered, the injection molding host is started, so that the molten slurry material is sprayed out from the injection molding nozzle by the injection molding host and is injected into the concave die body, then the injection molding host is transferred to a cooling position for cooling after molding, and finally recovery processing is carried out.

Description

Special full-automatic multiple operation processing all-in-one of coil casing

Technical Field

The invention relates to the technical field of coil shell processing equipment, in particular to a full-automatic multi-process processing all-in-one machine special for a coil shell.

Background

The coil is generally referred to as a ring-shaped wire winding, the most common coil applications include a motor, an inductor, a transformer, a loop antenna and the like, and the coil is generally required to be arranged in some shells when being arranged in corresponding devices or equipment;

the coil shell processing device has the following defects: in the processing process of the plastic shell used by the common coil, multiple devices are required to be used for carrying out multiple working procedures of molding, cooling, recycling and the like in sequence, so that the working efficiency is low, and the production efficiency is influenced.

Disclosure of Invention

The invention aims to provide a special full-automatic multi-process machining all-in-one machine for a coil shell, which aims to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: a full-automatic multi-process machining all-in-one machine special for a coil shell comprises a U-shaped supporting plate, wherein an electric sliding mechanism is connected to the upper left side of a bottom plate of the U-shaped supporting plate, a jacking mechanism is connected to the upper side of the electric sliding mechanism in an equidistance mode from left to right, a concave die body is connected to the upper side of the jacking mechanism, a lifting plate is horizontally arranged right above the concave die body, a convex die body is fixedly connected to the lower end face of the lifting plate in an equidistance mode from left to right, a first electric telescopic rod is vertically and fixedly connected to the central position of the upper end face of the lifting plate, the upper end of the first electric telescopic rod is fixedly connected to the upper end of the left side plate of the U-shaped supporting plate, an injection molding mechanism is fixedly mounted on the lifting plate above the position of each convex die body, a first proximity inductive switch is fixedly mounted, meanwhile, the first proximity inductive switch is electrically connected with the first electric telescopic rod, the outer wall of the fixed end of the first electric telescopic rod is connected with a second proximity inductive switch which is electrically connected with the electric sliding mechanism, a third proximity inductive switch is fixedly installed on the right side plate of the U-shaped support plate, the upper side of the right end of the U-shaped support plate is horizontally and fixedly connected with a cooling fan which is electrically connected with the third proximity inductive switch, a moving mechanism is fixedly connected on the U-shaped support plate where the cooling fan is located, the moving mechanism comprises a stepping motor, a third electric telescopic rod, a square frame, a rubber sleeve, a fourth proximity inductive switch and a fifth proximity inductive switch, the stepping motor is fixedly connected on the upper side of the right end of the U-shaped support plate, and the third electric telescopic rod is vertically and fixedly connected with the main shaft end of the stepping motor, the extension control circuit of the third electric telescopic rod is electrically connected with the third proximity inductive switch, the square frame is horizontally and fixedly connected with the left side of the lower end of the third electric telescopic rod, the rubber clamping sleeve is horizontally and fixedly connected with the inner side of the square frame, the fourth proximity inductive switch is fixedly installed at the lower sides of the left and right ends of the square frame, the fourth proximity inductive switch is electrically connected with the third electric telescopic rod and the electric sliding mechanism, the fourth proximity inductive switch is electrically connected with the stepping motor, the U-shaped support plate at the lower side position of the first proximity inductive switch is fixedly provided with the sixth proximity inductive switch, the sixth proximity inductive switch is electrically connected with the first electric telescopic rod, the rear side of the upper end of the right side plate of the U-shaped support plate is fixedly provided with the jacking mechanism, and the jacking mechanism comprises the fourth electric telescopic rod, Diaphragm, ejector pin and seventh proximity inductive switch, the vertical fixed connection of fourth electric telescopic handle is in the right side board upper end rear side of U type backup pad, diaphragm horizontal fixed connection is in fourth electric telescopic handle's lower extreme, the vertical fixed connection of ejector pin is in the diaphragm downside, the seventh proximity inductive switch front and back is in pairs fixed mounting be in the front and back end downside of diaphragm and seventh proximity inductive switch with the fourth electric telescopic handle electricity is connected, the fifth proximity inductive switch fixed mounting be in square frame about both ends upside and fifth proximity inductive switch with fourth electric telescopic handle circuit and third electric telescopic handle with the step motor electricity is connected.

Preferably, the injection molding mechanism comprises an injection molding host, a supporting hard pipe and injection molding nozzles, the injection molding host is arranged on the upper side of the lifting plate and is electrically connected with the first proximity inductive switch, the supporting hard pipe is fixedly connected to the discharge port of the injection molding host and between the lifting plates, and the injection molding nozzles are fixedly connected to the lower end of the supporting hard pipe and penetrate to the left side and the right side of the upper end of the convex die body.

Preferably, the injection molding main machine is arranged at the left side of the U-shaped supporting plate, the connecting guide rail is vertically and fixedly connected to the side plate of the U-shaped supporting plate, and the injection molding main machine is slidably connected to the connecting guide rail.

Preferably, the electric sliding mechanism comprises an electric guide rail and a supporting plate, the electric guide rail is horizontally and fixedly connected to the upper side of the U-shaped supporting plate, the supporting plate is horizontally and slidably connected to the upper side of the electric guide rail, meanwhile, the concave die body and the jacking mechanism are fixedly connected to the upper side of the supporting plate, and the electric guide rail is electrically connected with the second proximity inductive switch.

Preferably, the jacking mechanism comprises a second electric telescopic rod and a push plate, the second electric telescopic rod is vertically and fixedly connected to the outer side of the bottom of the concave die body, the push plate is embedded in the bottom surface of the concave die body, the upper end of the second electric telescopic rod penetrates through the bottom of the concave die body and is connected with the push plate, and the second electric telescopic rod extends to control the circuit to be electrically connected with the third proximity inductive switch through a time delay device.

Preferably, the lower end of the ejector rod is fixedly connected with an elastic rubber pad.

Preferably, a recovery box is placed on the U-shaped supporting plate below the position of the ejector rod.

Preferably, a clamping groove is formed in the U-shaped supporting plate at the position of the recycling box, and the recycling box is embedded in the clamping groove.

Preferably, the inner ring of the rubber clamping sleeve is provided with triangular rubber clamping teeth around the inner ring of the rubber clamping sleeve at equal intervals.

Compared with the prior art, the invention has the beneficial effects that:

1. the first electric telescopic rod is started to extend downwards, so that the lifting plate drives the die body to be correspondingly embedded into the female die body, and the port of the female die body is sealed by the lifting plate, the first proximity induction switch is triggered, the injection main machine is started, so that molten slurry materials are sprayed out from an injection nozzle by the injection main machine and injected into the female die body for forming, when the lifting plate descends, the first proximity induction switch is triggered, the first electric telescopic rod enters a preparation state of contraction, after a shell in the female die body is formed, the set time of the first electric telescopic rod delayer is just reached, then the first electric telescopic rod is lifted by the lifting plate with the die body, and then the second proximity induction switch generates induction so that the electric sliding mechanism drives the female die body to move to the right to leave;

2. when the concave die body moves rightwards and then triggers the third proximity inductive switch, the cooling fan is triggered and started to blow and cool a forming shell in the concave die body below, cooling is achieved, meanwhile, the third proximity inductive switch triggers the second electric telescopic rod to enable the second electric telescopic rod to enter a state of ready extension, after a certain time is reached, the second electric telescopic rod extends upwards, the formed shell is jacked upwards through a push plate, meanwhile, the third electric telescopic rod extends downwards, all rubber clamping sleeves are buckled on the shell which is lifted at each position through the square frame, the side wall of the inner ring of each rubber clamping sleeve is tightly wrapped on the shell, and meanwhile, when the square frame is pressed on the concave die body, the fourth proximity inductive switch triggers the third electric telescopic rod to lift the square frame upwards, and therefore, the rubber clamping sleeves drive the shell to lift;

3. the fourth approach induction switch of the invention causes the electric sliding mechanism to slide and reset the female die body leftwards, after the female die body slides and resets along with the electric sliding mechanism, the sixth approach induction switch is triggered, the first electric telescopic rod drives the male die body to descend into the female die body for secondary injection molding, the fourth approach induction switch causes the stepping motor to drive the square frame to rotate forwards to the lower side of the transverse plate, then the seventh approach induction switch generates induction, the fourth electric telescopic rod extends downwards, so that the ejector rod on the transverse plate translates downwards to penetrate through each rubber cutting sleeve, the shell in the rubber cutting sleeve is separated out to realize recovery, and the transverse plate is abutted to the upper side of the square frame, the fifth approach induction switch is triggered, so that the fifth approach induction switch is triggered, and the stepping motor drives the square frame to rotate and reset, and meanwhile, the third electric telescopic rod is contracted and reset, so that the next round of operation is convenient to carry out.

Drawings

FIG. 1 is a schematic view of the overall structure of a full-automatic multi-process machining integrated machine special for a coil shell according to the invention;

FIG. 2 is a schematic diagram of a top view structure of a connection between a square frame and a rubber ferrule in the full-automatic multi-process machining all-in-one machine for a coil housing according to the present invention;

FIG. 3 is a schematic diagram of a right-view structure of a top pressing mechanism connected with a U-shaped supporting plate in the full-automatic multi-process machining all-in-one machine special for coil casings of the present invention;

fig. 4 is a schematic structural diagram of a jacking mechanism in the full-automatic multi-process machining all-in-one machine special for the coil shell.

In the figure: 100. a U-shaped support plate; 101. a sixth proximity sensitive switch; 102. a concave die body; 103. a first proximity sensitive switch; 104. a convex mould body; 105. a lifting plate; 106. a first electric telescopic rod; 107. a second proximity sensitive switch; 108. a cooling fan; 109. a third proximity sensitive switch; 110. an injection molding mechanism; 111. an injection molding nozzle; 112. supporting the hard conduit; 113. injection molding the main machine; 114. connecting the guide rails; 120. a jacking mechanism; 121. a second electric telescopic rod; 122. pushing the plate; 130. an electric sliding mechanism; 131. a support plate; 132. an electric rail; 140. a moving mechanism; 141. a square frame; 142. a third electric telescopic rod; 143. a stepping motor; 144. a fourth proximity sensitive switch; 145. a fifth proximity sensitive switch; 146. a rubber ferrule; 147. triangular rubber latch; 150. a jacking mechanism; 151. a fourth electric telescopic rod; 152. a transverse plate; 153. a top rod; 154. an elastic rubber pad; 155. a seventh proximity sensitive switch; 160. a recycling bin; 170. a clamping groove.

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.

Referring to fig. 1-4, the present invention provides a technical solution: a full-automatic multi-process machining all-in-one machine special for a coil shell comprises a U-shaped supporting plate 100, wherein the left upper side of a bottom plate of the U-shaped supporting plate 100 is connected with an electric sliding mechanism 130, the upper side of the electric sliding mechanism 130 is connected with a jacking mechanism 120 in an equidistance from left to right, the upper side of the jacking mechanism 120 is connected with a concave body 102, a lifting plate 105 is horizontally arranged right above the concave body 102, the lower end surface of the lifting plate 105 is fixedly connected with a convex body 104 in an equidistance from left to right, the convex body 104 and the concave body 102 are matched, the central position of the upper end surface of the lifting plate 105 is vertically and fixedly connected with a first electric telescopic rod 106, the upper end of the first electric telescopic rod 106 is fixedly connected with the upper end of the left side plate of the U-shaped supporting plate 100, an injection mechanism 110 is fixedly installed on the lifting plate 105 on the upper side of the position of each convex body 104, a first proximity, meanwhile, the first proximity inductive switch 103 is electrically connected with a contraction control circuit of the first electric telescopic rod 106 through a time delay device, namely, after the first proximity inductive switch 103 is triggered, the first electric telescopic rod 106 enters a contraction preparation state, after a shell in the concave die body 102 is formed, the time just reaches the set time of the time delay device of the first electric telescopic rod 106, and then the first electric telescopic rod 106 drives the convex die body 104 to rise through the lifting plate 105; the outer wall of the fixed end of the first electric telescopic rod 106 is connected with a second proximity inductive switch 107, and the second proximity inductive switch 107 is electrically connected with the electric sliding mechanism 130, that is, when the first electric telescopic rod 106 drives the lifting plate 105 to ascend and reset, the second proximity inductive switch 107 generates induction to enable the electric sliding mechanism 130 to drive the concave mold body 102 to move away rightward; a third proximity inductive switch 109 is fixedly installed on the right side plate of the U-shaped support plate 100, a cooling fan 108 is horizontally and fixedly connected to the upper side of the right end of the U-shaped support plate 100, and the cooling fan 108 is electrically connected with the third proximity inductive switch 109, namely when the third proximity inductive switch 109 is triggered by the rightward movement of the concave die body 102, the cooling fan 108 is triggered to start, and blows air to the forming shell in the concave die body 102 below for cooling, so that cooling is realized; fixedly connected with moves mechanism 140 on the U type backup pad 100 of cooling fan 108 position, move mechanism 140 and include step motor 143, third electric telescopic handle 142, square frame 141, rubber cutting ferrule 146, fourth proximity inductive switch 144 and fifth proximity inductive switch 145, step motor 143 fixed connection is in U type backup pad 100 right-hand member upside and the main shaft end of step motor 143 is vertical downwards, the vertical fixed connection of third electric telescopic handle 142 is in the main shaft end of step motor 143, third electric telescopic handle 142 extends control circuit and third proximity inductive switch 109 and is connected through the delay ware electricity, square frame 141 horizontal fixed connection is in third electric telescopic handle 142 lower extreme left side, rubber cutting ferrule 146 horizontal fixed connection is inboard square frame 141 and rubber cutting ferrule 146 matches with processing casing outer lane size in die body 102, fourth proximity inductive switch 144 fixed mounting is in square frame 141 about both ends downside and fourth proximity inductive switch 144 and the shrink control of third electric telescopic handle 142 The circuit is electrically connected with a control circuit of the left slide of the electric sliding mechanism 130, and the fourth proximity inductive switch 144 is electrically connected with a control circuit of the forward rotation of the stepping motor 143, that is, when the third proximity inductive switch 109 is triggered, the third electric telescopic rod 142 enters an extension preparation state under the action of a time delay, when the jacking mechanism 120 jacks the molded shell from the concave mold body 102, the third electric telescopic rod 142 just extends downwards, all the rubber clamping sleeves 146 are buckled on the shell raised at various positions through the square frame 141, the side walls of the inner rings of the rubber clamping sleeves 146 are tightly wrapped on the shell, and when the square frame 141 is pressed on the concave mold body 102, the fourth proximity inductive switch 144 is triggered to enable the third electric telescopic rod 142 to lift up with the square frame 141, so that the rubber clamping sleeves 146 lift up with the shell, and simultaneously, the fourth proximity inductive switch 144 enables the electric sliding mechanism 130 to slide and reset to the left with the concave mold body 102, the stepping motor 143 drives the square frame 141 to rotate forward and backward; a sixth proximity induction switch 101 is fixedly installed on the U-shaped support plate 100 at the lower side of the first proximity induction switch 103, and the sixth proximity induction switch 101 is electrically connected with the extension circuit of the first electric telescopic rod 106, namely, after the concave die body 102 returns along with the sliding return of the electric sliding mechanism 130, the sixth proximity induction switch 101 is triggered, so that the first electric telescopic rod 106 drives the convex die body 104 to descend into the concave die body 102 for injection molding again; top pressure mechanism 150 is fixedly installed at the rear side of the upper end of the right side plate of the U-shaped supporting plate 100, the top pressure mechanism 150 comprises a fourth electric telescopic rod 151, a transverse plate 152, a push rod 153 and a seventh proximity induction switch 155, the fourth electric telescopic rod 151 is vertically and fixedly connected to the rear side of the upper end of the right side plate of the U-shaped supporting plate 100, the lower end of the fourth electric telescopic rod 151 is a telescopic end, the transverse plate 152 is horizontally and fixedly connected to the lower end of the fourth electric telescopic rod 151, the transverse plate 152 is located at a front-back trend position, the push rod 153 is vertically and fixedly connected to the lower side of the transverse plate 152, the push rod 153 is equidistantly distributed from left to right, the seventh proximity induction switch 155 is longitudinally and fixedly installed at the lower side of the front-back end of the transverse plate 152 in pairs, the seventh proximity induction switch 155 is electrically connected with an extension control circuit of the fourth electric telescopic rod 151, the fifth proximity induction switch 145 is fixedly installed The step motor 143 is electrically connected to the reverse control circuit, when the step motor 143 drives all the molded housings in the rubber sleeve 146 to move to the lower side of the horizontal plate 152 through the square frame 141, then the seventh proximity sensing switch 155 generates sensing, so that the fourth electric telescopic rod 151 extends downwards, so that the ejector rod 153 on the horizontal plate 152 translates downwards to pass through each rubber sleeve 146, so that the housings in the rubber sleeves 146 are separated, recovery is realized, the horizontal plate 152 abuts against the upper side of the square frame 141, so that the fifth proximity sensing switch 145 is triggered, so that the fifth proximity sensing switch is triggered, so that the step motor 143 drives the square frame 141 to rotate and reset, and meanwhile, the third electric telescopic rod 142 contracts and resets, and the next round of operation is facilitated.

The injection molding mechanism 110 comprises an injection molding host 113, a supporting hard conduit 112 and an injection molding nozzle 111, the injection molding host 113 is arranged on the upper side of the lifting plate 105, the injection molding host 113 is electrically connected with the first proximity inductive switch 103, the supporting hard conduit 112 is vertically and fixedly connected between a discharge port of the injection molding host 113 and the lifting plate 105, the injection molding nozzle 111 is fixedly connected to the lower end of the supporting hard conduit 112 and the injection molding nozzle 111 penetrates to the left side and the right side of the upper end of the convex mold body 104, the first electric telescopic rod 106 is started to extend downwards, so that the lifting plate 105 with the convex mold body 104 correspondingly embedded into the concave mold body 102 and the lifting plate 105 seals the port of the concave mold body 102, the first proximity inductive switch 103 is triggered, the injection molding host 113 is started, and the injection molding host 113 sprays molten slurry material from the injection.

The U-shaped support plate 100 side plate at the left side of the injection molding main machine 113 is vertically and fixedly connected with a connecting guide rail 114, the injection molding main machine 113 is connected in the connecting guide rail 114 in a sliding mode through a sliding block, and the connecting guide rail 114 enables the injection molding main machine 113 to stably slide up and down.

The electric sliding mechanism 130 comprises an electric guide rail 132 and a supporting plate 131, the electric guide rail 132 is horizontally and fixedly connected to the upper side of the U-shaped supporting plate 100, the supporting plate 131 is horizontally and slidably connected to the upper side of the electric guide rail 132, meanwhile, the concave body 102 and the jacking mechanism 120 are both fixedly connected to the upper side of the supporting plate 131, the electric guide rail 132 is electrically connected with the second proximity inductive switch 107, namely, when the second proximity inductive switch 107 is triggered, the electric guide rail 132 drives the concave body 102 to move rightwards through the supporting plate 131.

The jacking mechanism 120 comprises a second electric telescopic rod 121 and a push plate 122, the second electric telescopic rod 121 is vertically and fixedly connected to the outer side of the bottom of the die body 102, the push plate 122 is embedded on the inner bottom surface of the die body 102, the upper end of the second electric telescopic rod 121 penetrates through the bottom of the die body 102 and is connected with the push plate 122, the second electric telescopic rod 121 is extended and controlled by a control circuit and a third proximity inductive switch 109, and is electrically connected with a time delay device, namely, when the die body 102 moves to the right side of the U-shaped supporting plate 100, the third proximity inductive switch 109 triggers the second electric telescopic rod 121, so that the second electric telescopic rod enters a state to be extended, after a certain time is reached, the second electric telescopic rod 121 is extended upwards, and the shell formed.

An elastic rubber pad 154 is fixedly connected to the lower end of the top rod 153, and the elastic rubber pad 154 prevents the top rod 153 from damaging the shell.

The recovery box 160 is placed on the U-shaped support plate 100 below the position of the push rod 153, and the recovery box 160 is used for receiving the pushed-down shell.

The U-shaped support plate 100 at the position of the recycling bin 160 is provided with a clamping groove 170, the recycling bin 160 is embedded in the clamping groove 170, and the clamping groove 170 facilitates the recycling bin 160 to be stably positioned at the lower side of the push rod 153.

The inner ring of the rubber clamping sleeve 146 is provided with triangular rubber clamping teeth 147 at equal intervals, and the triangular rubber clamping teeth 147 facilitate the stable clamping of the processed shell

The working principle is as follows: when the first electric telescopic rod 106 is started to extend downwards, so that the lifting plate 105 drives the convex die body 104 to be correspondingly embedded into the concave die body 102 and the lifting plate 105 seals the port of the concave die body 102, the first proximity inductive switch 103 is triggered, the injection main machine 113 is started, so that molten slurry materials are sprayed out from the injection nozzle 111 by the injection main machine 113 and injected into the concave die body 102 for forming, and when the lifting plate 105 descends, the first proximity inductive switch 103 is triggered, the first electric telescopic rod 106 enters a contraction preparation state, after a shell in the concave die body 102 is formed, the set time of a time delay device of the first electric telescopic rod 106 is just reached, then the first electric telescopic rod 106 drives the convex die body 104 to rise through the lifting plate 105, then the second proximity inductive switch 107 generates induction to enable the electric sliding mechanism 130 to drive the concave die body 102 to move rightwards, then the concave die body 102 moves rightwards, and then the third proximity inductive switch 109 is triggered, the cooling fan 108 is triggered to start, the formed shell in the concave die body 102 below is blown to cool, cooling is achieved, meanwhile, the third proximity inductive switch 109 triggers the second electric telescopic rod 121 to enable the second electric telescopic rod to enter a ready-to-extend state, after a certain time is reached, the second electric telescopic rod 121 extends upwards, the formed shell is jacked upwards through the push plate 122, meanwhile, the third electric telescopic rod 142 just extends downwards, all the rubber clamping sleeves 146 are buckled on the shell which is lifted at each position through the square frame 141, the side walls of the inner rings of the rubber clamping sleeves 146 are tightly wrapped on the shell, meanwhile, when the square frame 141 is pressed on the concave die body 102, the fourth proximity inductive switch 144 is triggered to enable the third electric telescopic rod 142 to lift the square frame 141 upwards, so that the rubber clamping sleeves 146 lift the shell, and meanwhile, the fourth proximity inductive switch 144 enables the electric sliding mechanism 130 to slide and reset leftwards with the concave die body 102, after the concave body 102 returns to the sliding position along with the electric sliding mechanism 130, the sixth proximity inductive switch 101 is triggered, so that the first electric telescopic rod 106 lowers the convex body 104 into the concave body 102, and the second injection molding process is performed, and the fourth proximity inductive switch 144 enables the stepping motor 143 to drive the square frame 141 to rotate forward to the lower side of the horizontal plate 152, then the seventh proximity inductive switch 155 generates induction, so that the fourth electric telescopic rod 151 extends downward, so that the top rod 153 on the horizontal plate 152 translates downward to pass through each rubber sleeve 146, so that the housing in the rubber sleeve 146 is separated out, the recycling is realized, the horizontal plate 152 abuts against the upper side of the square frame 141, the fifth proximity inductive switch 145 is triggered, so that the fifth proximity induction is triggered, the fifth proximity inductive switch triggers the stepping motor 143 to drive the square frame 141 to rotate to return, and the third electric telescopic rod 142 retracts to return, the next round of operation is convenient to carry out.

It is noted that, herein, 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.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (9)

1. The utility model provides a special full-automatic multiple operation processing all-in-one of coil casing, includes U type backup pad (100), its characterized in that: the side of the upper left side of the bottom plate of U-shaped supporting plate (100) is connected with electric sliding mechanism (130), electric sliding mechanism (130) upside is connected with climbing mechanism (120) from a left side to turn right equidistance, climbing mechanism (120) upside is connected with die body (102), level is provided with lifter plate (105) directly over die body (102), the terminal surface is turning right equidistance fixedly connected with die body (104) from a left side under lifter plate (105), the up end central point of lifter plate (105) puts the upper end fixed connection of the first electric telescopic handle (106) of vertical fixedly connected with and first electric telescopic handle (106) U-shaped supporting plate (100) left side board upper end, every the position upside of die body (104) the last fixed mounting of lifter plate (105) has injection molding machine structure (110), die body (102) upper end left side position fixed mounting has first proximity inductive switch (103) and first proximity induction switch on U-shaped supporting plate (100) lateral wall The reaction switch (103) is electrically connected with the injection molding mechanism (110), meanwhile, the first proximity inductive switch (103) is electrically connected with the first electric telescopic rod (106), the outer wall of the fixed end of the first electric telescopic rod (106) is connected with the second proximity inductive switch (107), the second proximity inductive switch (107) is electrically connected with the electric sliding mechanism (130), the right side plate of the U-shaped support plate (100) is fixedly provided with the third proximity inductive switch (109), the upper side of the right end of the U-shaped support plate (100) is horizontally and fixedly connected with the cooling fan (108), the cooling fan (108) is electrically connected with the third proximity inductive switch (109), the U-shaped support plate (100) at the position of the cooling fan (108) is fixedly connected with the moving mechanism (140), and the moving mechanism (140) comprises a stepping motor (143), a third electric telescopic rod (142), A square frame (141), a rubber clamping sleeve (146), a fourth proximity inductive switch (144) and a fifth proximity inductive switch (145), wherein the stepping motor (143) is fixedly connected to the upper side of the right end of the U-shaped supporting plate (100), the third electric telescopic rod (142) is vertically and fixedly connected to the main shaft end of the stepping motor (143), the extension control circuit of the third electric telescopic rod (142) is electrically connected to the third proximity inductive switch (109), the square frame (141) is horizontally and fixedly connected to the left side of the lower end of the third electric telescopic rod (142), the rubber clamping sleeve (146) is horizontally and fixedly connected to the inner side of the square frame (141), the fourth proximity inductive switch (144) is fixedly installed at the lower sides of the left and right ends of the square frame (141), and the fourth proximity inductive switch (144) is electrically connected to the third electric telescopic rod (142) and the electric sliding mechanism (130), the fourth proximity induction switch (144) is electrically connected with the stepping motor (143), a sixth proximity induction switch (101) is fixedly installed on the U-shaped supporting plate (100) at the lower side of the first proximity induction switch (103), the sixth proximity induction switch (101) is electrically connected with the first electric telescopic rod (106), a jacking mechanism (150) is fixedly installed at the rear side of the upper end of the right side plate of the U-shaped supporting plate (100), the jacking mechanism (150) comprises a fourth electric telescopic rod (151), a transverse plate (152), a jacking rod (153) and a seventh proximity induction switch (155), the fourth electric telescopic rod (151) is vertically and fixedly connected to the rear side of the upper end of the right side plate of the U-shaped supporting plate (100), the transverse plate (152) is horizontally and fixedly connected to the lower end of the fourth electric telescopic rod (151), and the jacking rod (153) is vertically and fixedly connected to the lower side of the transverse plate (152), the seventh proximity induction switch (155) is fixedly mounted on the lower sides of the front end and the rear end of the transverse plate (152) in a front-rear paired mode, the seventh proximity induction switch (155) is electrically connected with the fourth electric telescopic rod (151), the fifth proximity induction switch (145) is fixedly mounted on the upper sides of the left end and the right end of the square frame (141), and the fifth proximity induction switch (145) is electrically connected with the fourth electric telescopic rod (151) circuit, the third electric telescopic rod (142) and the stepping motor (143).

2. The special full-automatic multi-process machining all-in-one machine for the coil shell as claimed in claim 1, characterized in that: injection moulding mechanism (110) including moulding plastics host computer (113), support hard pipe (112) and injection moulding nozzle (111), it sets up to mould plastics host computer (113) lifter plate (105) upside and mould plastics host computer (113) with first proximity inductive switch (103) electricity is connected, support the vertical fixed connection of hard pipe (112) mould plastics the discharge port of host computer (113) with between lifter plate (105), injection moulding nozzle (111) fixed connection be in support hard pipe (112) lower extreme and injection moulding nozzle (111) wear to the left and right sides of convex mould body (104) upper end.

3. The full-automatic multi-process machining all-in-one machine special for the coil shell as claimed in claim 2, characterized in that: the injection molding main machine (113) is arranged at the left side of the U-shaped support plate (100), a connecting guide rail (114) is vertically and fixedly connected to the side plate of the U-shaped support plate (100), and the injection molding main machine (113) is connected into the connecting guide rail (114) in a sliding mode.

4. The special full-automatic multi-process machining all-in-one machine for the coil shell as claimed in claim 1, characterized in that: electric sliding mechanism (130) include electronic guide rail (132) and layer board (131), electronic guide rail (132) horizontal fixed connection be in the upside of U type backup pad (100), layer board (131) horizontal sliding connection be in electronic guide rail (132) upside, simultaneously die body (102) with climbing mechanism (120) all fixed connection be in layer board (131) upside, electronic guide rail (132) with second is close inductive switch (107) electricity and is connected.

5. The special full-automatic multi-process machining all-in-one machine for the coil shell as claimed in claim 1, characterized in that: climbing mechanism (120) include second electric telescopic handle (121) and push pedal (122), the vertical fixed connection of second electric telescopic handle (121) is in the die body (102) bottom outside, push pedal (122) gomphosis is in on the bottom surface in die body (102) and second electric telescopic handle (121) upper end is passed die body (102) bottom and is being connected push pedal (122), second electric telescopic handle (121) extension control circuit with third proximity inductive switch (109) are connected through the time delay ware electricity.

6. The special full-automatic multi-process machining all-in-one machine for the coil shell as claimed in claim 1, characterized in that: an elastic rubber pad (154) is fixedly connected to the lower end of the top rod (153).

7. The special full-automatic multi-process machining all-in-one machine for the coil shell as claimed in claim 1, characterized in that: a recovery box (160) is arranged on the U-shaped support plate (100) below the position of the ejector rod (153).

8. The full-automatic multi-process machining all-in-one machine special for the coil shell as claimed in claim 7, characterized in that: a clamping groove (170) is formed in the U-shaped supporting plate (100) where the recovery box (160) is located, and the recovery box (160) is embedded in the clamping groove (170).

9. The special full-automatic multi-process machining all-in-one machine for the coil shell as claimed in claim 1, characterized in that: and triangular rubber clamping teeth (147) are arranged around the inner ring of the rubber clamping sleeve (146) at equal intervals.

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