CN114903353B - Dish heat preservation device and processing equipment and processing method of key parts thereof - Google Patents

Abstract

The application discloses a dish heat preservation device and processing equipment and a processing method of key components thereof, wherein the dish heat preservation device comprises a heat preservation furnace body, a heat preservation heating connection unit and a heat conduction holding unit, wherein the heat preservation furnace body is sequentially provided with an appliance placing cavity, a furnace chamber and a control bin from top to bottom; the heat-preserving heating connection unit comprises a furnace chamber cover plate and a heating shell, wherein the heating shell is internally connected with a heating pipe and a first spring, the lower side of the first spring is propped against the furnace chamber cover plate, the heating shell is connected into a heat-preserving furnace body through a furnace chamber, the furnace chamber cover plate is fixedly connected into the heat-preserving furnace body at the lower side of the furnace chamber, and a temperature sensor is fixedly connected into the heating shell close to the heating pipe; the dish containing and heat conducting unit comprises a dish containing device with an upward opening, one downward end of the dish containing device is connected with a heat conducting device in a threaded manner, the upper side of the heat conducting device is flush with the lower side of the opening, the dish containing device is supported on the heat-preserving furnace body through the device placing cavity, and one downward side of the heat conducting device is abutted against the upper side of the heating shell; the application is convenient for placing and preserving dishes.

Description

Dish heat preservation device and processing equipment and processing method of key parts thereof

Technical Field

The application relates to the technical field of food heat preservation, in particular to a dish heat preservation device and processing equipment and a processing method of key parts of the dish heat preservation device.

Background

Along with the improvement of the living standard of people, restaurants and family dinner become important living modes of communication and communication of people, and in the dining process, because of the large number of dishes and the lengthening of chat communication time, some dishes are easy to cool so as to influence the taste of the dishes, and physical discomfort can be caused when the dishes are serious, so that the dish and dish heat preservation device is quite important in high-quality dinner. At present, most of dish heat preservation devices used in the market are open-fire furnaces, electric heating flat-plate type and the like, when the open-fire furnaces are used, the open-fire furnaces are unsafe, personnel are extremely easy to scald, the electric heating flat-plate type dish heat preservation devices basically drag long wires, the electric heating flat-plate type dish heat preservation devices basically have no dish anti-skid function, the use is inconvenient and unsafe, and a new dish heat preservation device is needed to be designed to solve the technical problem that the dish heat preservation devices in the prior art are inconvenient to use.

Disclosure of Invention

This section is intended to outline some aspects of embodiments of the application and to briefly introduce some preferred embodiments. Some simplifications or omissions may be made in this section as well as in the description of the application and in the title of the application, which may not be used to limit the scope of the application.

The present application has been made in view of the above and/or existing problems with the insulation of dishes.

Therefore, the application aims to provide a dish heat preservation device and processing equipment and a processing method of key components thereof, which are convenient for placing and preserving dishes by the design of a dish container and a heat conductor, and use specific processing equipment to cover the dish container and the heat conductor respectively, thereby being convenient to process and high in efficiency.

In order to solve the technical problems, the application provides the following technical scheme: a dish heat preservation device, which comprises,

the device comprises a heat-preserving furnace body, wherein an appliance placing cavity is formed in one upward end of the heat-preserving furnace body, a control bin is arranged in one downward end of the heat-preserving furnace body, and a furnace chamber is arranged in the heat-preserving furnace body between the control bin and the appliance placing cavity;

the heat-preserving heating connection unit comprises a furnace chamber cover plate and a heating shell, wherein the heating shell is internally connected with a heating pipe and a first spring, the heating shell is connected into a heat-preserving furnace body through a furnace chamber, the furnace chamber cover plate is fixedly connected into the heat-preserving furnace body at the lower side of the furnace chamber, and the lower side of the first spring is abutted against the furnace chamber cover plate;

hold heat conduction unit, hold heat conduction unit including having upwards open-ended dish and hold the ware, dish hold ware one end threaded connection down has the heat conduction ware, the upside and the open-ended downside of heat conduction ware flush, the dish holds the ware and lays the chamber through the utensil and support on the heat preservation furnace body, the upside at the shell that generates heat is contradicted to one side that the heat conduction ware is down.

As a preferable scheme of the dish heat preservation device, the application comprises the following steps: the heat preservation heating connection unit further comprises a control bin cover plate which is fixedly connected with the heat preservation furnace body and arranged at the lower side of the control bin, a control circuit board and a power supply are connected to the upper side of the control bin cover plate, a first lead hole and a second lead hole are formed in the furnace chamber cover plate, an electric wire is connected to the heating tube, the lower end of the electric wire penetrates through the first lead hole and is connected with the power supply, a data wire is connected to the temperature sensor, and the data wire penetrates through the second lead hole and is connected with the control circuit board.

As a preferable scheme of the dish heat preservation device, the application comprises the following steps: the dish is held ware one end down and is opened there is the step hole, the cover is equipped with the sealing washer on the heat conduction ware, and the periphery of heat conduction ware lower part is equipped with the external screw thread, the heat conduction ware is held ware lower part at the dish through step hole threaded connection, and the heat conduction ware compresses tightly the sealing washer on the dish holds the ware.

The equipment for processing the dish container comprises a bottom plate and an upper mold core, wherein a plurality of first limiting pipes are arranged on the upper side of the bottom plate, a second spring is arranged in each first limiting pipe, a vibrating plate is arranged above the bottom plate, a second limiting pipe is arranged on the lower side of each vibrating plate, a plurality of first guide posts are arranged on each mold in the second limiting pipes, a mold cavity is formed in one end of each mold, a plurality of first guide posts are arranged on each upper mold core in one-to-one correspondence, the upper mold cores are inserted into the first guide posts through the first guide holes, the lower sides of the upper mold cores are abutted to the upper sides of the molds, the vibrating plates are connected with lower mold cores in threaded mode, the bottom sides of the upper mold cores are abutted to the upper surfaces of the lower mold cores, a plurality of casting holes are arranged on the upper mold cores, and a first casting cavity is formed in the outer edges of the mold cavities, the outer sides of the lower mold cores and the lower sides of the mold cores.

As a preferable scheme of the processing equipment of the dish container, the application comprises the following steps: the vibrating plate downside fixedly connected with vibrating motor of lower mold core one end, the vibrating plate downside fixedly connected with weight and the same balancing weight of vibrating motor of lower mold core other end.

The equipment for processing the heat conductor comprises a bottom die, a left die, a right die and a processing die core, wherein a processing sinking groove is formed in one side of the center of the bottom die, a plurality of second guide posts are arranged on the upper side of the bottom die outside the processing sinking groove, a plurality of first sliding grooves are arranged on the left die, a plurality of second sliding grooves are arranged on the right die, the left die is inserted into the corresponding second guide posts through the first sliding grooves, the right die is inserted into the corresponding second guide posts through the second sliding grooves, a first processing half hole is formed in the center of the left die, a second processing half hole identical to the first processing half hole is formed in the center of the right die, the lower side of the left die is abutted against the upper side of the bottom die, the lower side of the right die is abutted against the upper side of the bottom die, one side of the left die and one side of the right die are combined together, a plurality of second guide holes corresponding to the second guide posts are arranged on the processing die core, the processing die casting holes and air outlet holes are formed in the processing side of the left die and the right die core which are combined together after being inserted into the second guide holes, and the processing half hole is formed in the processing half hole, and the same shape of the outer edge of the die casting die is formed between the first processing half hole, the first processing half hole and the outer edge of the heat conductor.

As a preferable mode of the processing apparatus of the heat conductor of the present application, wherein: the bottom die of the outer fringe center both sides of processing heavy groove all is equipped with spacing post, one side that the relative right mould of left side set up is equipped with the left location half hole that corresponds with spacing post, and one side that the relative left mould of right side set up is equipped with the right location half hole that corresponds with spacing post, when left mould and right mould are in the same place, left location half hole and right location half hole just encircle corresponding spacing post.

As a preferable mode of the processing apparatus of the heat conductor of the present application, wherein: the left side that left side mould kept away from the right mould is equipped with left handle, and the right side that the right mould kept away from the left mould is equipped with right handle.

A method for processing a dish container by using processing equipment of the dish container, comprising the following steps,

firstly, a plurality of second springs are put into a first limiting pipe;

fixing the mold on the vibration plate by using a first threaded hole formed in the vibration plate by screwing a screw into the mold and a second threaded hole formed in the mold, wherein the first threaded through hole in the center of the vibration plate is coaxial with the second threaded through hole in the center of the mold;

sleeving a plurality of second limiting pipes on the lower side of the vibrating plate into the upper ends of the second springs;

sleeving the upper mold core into a first guide post through a first guide hole, so that the upper mold core is tightly pressed on the mold;

screwing the lower die core into the first threaded through hole and continuing screwing the lower die core into the second threaded through hole by utilizing the external threads on the periphery of the lower die core until the upper surface of the lower die core is contacted with the lower surface of the upper die core;

applying casting material into the first casting material cavity through the casting material hole;

and (3) opening the vibrating motor, compacting and uniformly casting materials in the first casting cavity under the action of the second spring, closing the vibrating motor after the casting materials are molded for a period of time, unscrewing the lower mold core, taking out the upper mold core, and taking out the cast dish container.

A method for processing a heat conductor using a processing apparatus for a heat conductor, comprising the steps of,

the left die is sleeved into the second guide post through the first chute, the right die is sleeved into the second guide post through the second chute, the left die and the right die are pushed to be matched, and the limiting column limits the left die and the right die;

sleeving the processing mold core on the second guide post, so that the processing mold core is abutted against the upper sides of the left mold and the right mold which are combined together;

the molten casting material is die-cast into a second casting cavity through a die-casting hole, and the air outlet hole is utilized for exhausting;

and after the casting material is cooled, the processing mold core is started, the left mold and the right mold are pulled outwards, and the heat conductor which is molded by the die casting is taken out.

The application has the beneficial effects that: in the dish heat preservation device, the dish containing device connected with the heat conductor is directly placed in the device placing cavity of the heat preservation furnace body, the bottom side of the heat conductor is abutted against the upper surface of the heating shell, the heating tube heats the heating shell and is conducted into the dish containing device through the heat conductor, and the dish containing device is heat-conducting and heat-preserving for dishes in the dish containing device and is convenient to use; the dish container and the heat conductor are processed by the processing equipment and the corresponding method, which are designed in the application, and the processing is convenient and the efficiency is high.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are needed in the description of the embodiments will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present application, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art. Wherein:

FIG. 1 is a diagram showing the internal structure of the dish heat preservation device of the present application.

Fig. 2 is a front view of the dish heat preservation device of the present application.

Fig. 3 is a diagram showing an internal structure of the heat-insulating furnace body according to the present application.

Fig. 4 is a bottom view of the insulating furnace of the present application.

FIG. 5 is a schematic view of a heat-generating enclosure of the present application.

Fig. 6 is a bottom view of the heat generating tube of the present application connected to the inside of the heat generating housing.

Fig. 7 is a top view of a cavity cover plate in the dish insulation apparatus of the present application.

Fig. 8 is a top view of the installation of a control cabin cover plate in the dish heat preservation device of the application.

Fig. 9 is a cross-sectional view of a dish holder in the device of the present application.

Fig. 10 is a cross-sectional view of a heat conductor in a dish insulation apparatus of the present application.

Fig. 11 is a front view of a heat conductor in a dish insulation apparatus of the present application.

Fig. 12 is a front view of a processing apparatus for a dish holder according to the present application.

Fig. 13 is an installation sectional view of a processing apparatus of a dish container according to the present application.

Fig. 14 is a bottom view of a vibrating plate in the processing apparatus of the dish holder of the present application.

Fig. 15 is a top view of a mold in the processing apparatus of the dish holder of the present application.

Fig. 16 is a bottom view of a mold in a processing apparatus for a dish holder according to the present application.

FIG. 17 is a bottom view of the upper mold core in the processing apparatus of the dish container of the present application.

Fig. 18 is a schematic view of a lower mold core in the processing device of the dish container of the present application.

Fig. 19 is a front view of a processing apparatus of the heat conductor in the present application.

Fig. 20 is an installation sectional view of a processing apparatus of a heat conductor in the present application.

Fig. 21 is a front view of a bottom die in a processing apparatus of a heat exchanger according to the present application.

Fig. 22 is a top view of a bottom die in a processing apparatus of a heat exchanger according to the present application.

Fig. 23 is a top view of a left die and a right die in a processing apparatus of a heat conductor according to the present application.

Fig. 24 is a front view of a processing core in the processing apparatus of the heat conductor in the present application.

Fig. 25 is a plan view of a processing core in the processing apparatus of the heat conductor in the present application.

In the figure, a 100 dish heat preservation device, a 101 heat preservation furnace body, a 101a control bin, a 101b appliance placing cavity, a 101c ring groove, a 101d furnace cavity, a 101e sliding groove, a 101f second thread counter bore, a 101g first thread counter bore, a 102 holding heat conduction unit, a 102a dish container, a 102a-1 step hole, a 102a-2 opening, a 102b heat conduction unit, a 102b-1 external thread, a 102c sealing ring, a 103 heat preservation heating connection unit, a 103a temperature sensor, a 103b heating tube, a 103b-1 positive electrode, a 103b-2 negative electrode, a 103c first spring, a 103d heating shell, a 103d-1 center counter bore, a 103d-2 ear, a 103e wire, a 103f power supply, a 103g furnace cavity cover plate, a 103g-1 first lead hole, a 103g-2 second lead hole, a 103g-3 positioning tube, a 103g-4 second connection hole, a 103h control bin cover plate, a 103h-1 first connection hole, a 103h-2 partition plate, a 103h-3 heat dissipation plate, a 103i control circuit j data line, 200 dish container processing equipment, 201 balancing weights, 202 bottom plates, 202a first limiting pipes, 203 vibrating motors, 204 second springs, 205 vibrating plates, 205a second limiting pipes, 205b first guide posts, 205c fixing holes, 206 upper mold cores, 206a first handles, 206b casting holes, 206c first guide holes, 207 molds, 207a third threaded counter bores, 208 lower mold cores, 208a polygonal steps, 209 first casting cavities, 300 heat conductor processing equipment, 301 right molds, 301a right handles, 301b second processing half holes, 301c right positioning half holes, 301d second sliding grooves, 302 bottom molds, 302a second guide posts, 302b limiting columns, 302c processing sinking grooves, 303 left molds, 303a left handles, 303b first processing half holes, 303c first sliding grooves, 303d left positioning half holes, 304 processing mold cores, 304a second handles, 304b die casting holes, 304c air outlet holes, 304d second guide holes, 305 a second casting cavity.

Detailed Description

In order that the above-recited objects, features and advantages of the present application will become more readily apparent, a more particular description of the application will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present application, but the present application may be practiced in other ways other than those described herein, and persons skilled in the art will readily appreciate that the present application is not limited to the specific embodiments disclosed below.

Further, reference herein to "one embodiment" or "an embodiment" means that a particular feature, structure, or characteristic can be included in at least one implementation of the application. The appearances of the phrase "in one embodiment" in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments.

Example 1

Referring to fig. 1 to 11, a first embodiment of the present application provides a dish heat preservation device 100, which is convenient to use and achieves heat preservation of dishes.

A dish heat preservation device 100 comprises a heat preservation furnace body 101, a ring groove 101c is arranged on the outer side of the heat preservation furnace body 101, the weight of the heat preservation furnace body 101 can be reduced, the heat preservation furnace body 101 can be conveniently taken and placed, an appliance placing cavity 101b is arranged at one upward end of the heat preservation furnace body 101, a control cabin 101a is arranged at one downward end of the heat preservation furnace body 101, a furnace chamber 101d is arranged in the heat preservation furnace body 101 between the control cabin 101a and the appliance placing cavity 101b, a heat preservation heating connection unit 103 is connected in the heat preservation furnace body 101, the heat preservation heating connection unit 103 comprises a furnace chamber cover plate 103g and a heating shell 103d, a sliding groove 101e is arranged in the heat preservation furnace body 101 connected with the upper side of the control cabin 101a, a plurality of lugs 103d-2 are distributed on the outer side of the heating shell 103d-2, the lugs 103d-2 can just slide into the heat preservation furnace body 101 through the sliding groove 101e, a center counter bore 103d-1 is arranged on one downward side of the heating shell 103d, the central counter bore 103d-1 of the heating shell 103d is connected with a heating tube 103b and a first spring 103c, the upper side of the center of the furnace chamber cover plate 103g is provided with a positioning tube 103g-3, the lower part of the first spring 103c is arranged in the positioning tube 103g-3, the lower side of the first spring 103c is propped against the furnace chamber cover plate 103g, the heating shell 103d is connected into the heat preservation furnace body 101 through the furnace chamber 101d, the furnace chamber cover plate 103g is fixedly connected into the heat preservation furnace body 101 at the lower side of the furnace chamber 101d, in particular, the heat preservation furnace body 101 outside the furnace chamber 101d is provided with a plurality of second threaded counter bores 101f, the furnace chamber cover plate 103g is provided with a plurality of second connecting holes 103g-4 which are in one-to-one correspondence with the second threaded counter bores 101f, the furnace chamber cover plate 103g is fixedly connected onto the heat preservation furnace body 101 through the second connecting holes 103g-4 by fastening screws, the inside the heating shell 103d close to the heating tube 103b is fixedly connected with a temperature sensor 103a, the heat-preserving furnace body 101 is connected with a heat-conducting unit 102 on one side upwards, the heat-conducting unit 102 comprises a dish container 102a with an opening 102a-2 upwards, the dish container 102a is preferably made of ceramic materials, a heat conductor 102b is connected to one end of the dish container 102a downwards in a threaded mode, the heat conductor 102b is preferably made of food-grade stainless steel materials, the upper side of the heat conductor 102b is flush with the lower side of the opening 102a-2, the dish container 102a is supported on the heat-preserving furnace body 101 through an appliance placing cavity 101b, and one downward side of the heat conductor 102b is abutted to the upper side of a heating shell 103 d.

In order to further realize heating of the heating tube 103b, the heat-preserving and heating connection unit 103 further comprises a control bin cover plate 103h fixedly connected to the inside of the heat-preserving furnace body 101 and arranged on the lower side of the control bin 101a, a plurality of first threaded counter bores 101g are arranged on one side, facing downwards, of the heat-preserving furnace body 101 outside the control bin 101a, a plurality of first connection holes 103h-1 corresponding to the first threaded counter bores 101g one by one are arranged on the control bin cover plate 103h, fastening screws are used for screwing into the first threaded counter bores 101g after passing through the first connection holes 103h-1, the control bin cover plate 103h is fixedly connected to the heat-preserving furnace body 101, a control circuit board 103i and a power supply 103f are connected to the upper side of the control bin cover plate 103h, a partition plate 103h-2 separating the control circuit board 103i from the power supply 103f is arranged on the upper side of the control bin cover plate 103h, a plurality of heat dissipation holes 103h-3 are arranged on the control bin cover plate 103h, overheating in the heat-preserving furnace body 101 is prevented, a first lead holes 103g-1 and second lead holes 103g-2 are formed in the cover plate 103g, two ends of the heating tube 103b are provided with positive lead wires 103b-1 and negative lead wires 103b-2, and a data lead wires 103b-2 are connected to the negative lead wires 103 j-103 j and the negative lead wire 103b-2 through the positive lead wires and the lead wires 103b-2 and the negative lead wires 103b and the lead wire 103b and the negative wire 103b and the positive lead wires 103b 2 and the negative wire 103b 2.

In order to further improve the sealing performance of the heat conductor 102b and the dish container 102a and prevent the soup leaked in the dish container 102a from flowing downwards, one end of the dish container 102a facing downwards is provided with a step hole 102a-1, a sealing ring 102c is sleeved on the heat conductor 102b, the periphery of the lower part of the heat conductor 102b is provided with an external thread 102b-1, the heat conductor 102b is connected to the lower part of the dish container 102a through the step hole 102a-1 in a threaded manner, and the heat conductor 102b compresses the sealing ring 102c on the dish container 102a.

The control circuit board 103i is electrically connected with the power supply 103f, the temperature sensor 103a sends the acquired temperature signal to the control circuit board 103i, the control circuit board 103i controls the power supply 103f to be powered on and off according to the received temperature signal, the power supply 103f in the embodiment is preferably a rechargeable battery, a charging connector mounting groove is formed in the heat preservation furnace body 101, and a charging connector can be mounted at the charging connector mounting groove so as to charge the rechargeable battery conveniently; when the heat preservation dishes are needed, the dishes container 102a connected with the heat conductor 102b is directly placed in the appliance placing cavity 101b of the heat preservation furnace body 101, and the bottom side of the heat conductor 102b is abutted against the upper surface of the heating shell 103 d; the temperature sensor 103a detects the temperature of the heating shell 103d near the heating tube 103b, if the temperature is smaller than a set heating temperature threshold, the power supply 103f is continuously conducted to electrify and heat the heating tube 103b, when the detected temperature exceeds the set heating temperature threshold, the control circuit board 103i controls the power supply 103f to cut off the power supply, the heating tube 103b stops heating the heating shell 103d, the heating tube 103b conducts heat to the heating shell 103d, and then the heat is conducted into the dish containing device 102a through the heat conductor 102b to conduct heat conduction and heat preservation to dishes in the dish containing device 102a, and the use is convenient.

Example 2

Referring to fig. 12 to 18, in a second embodiment of the present application, the present embodiment is different from embodiment 1 in that a processing apparatus 200 for a dish container is provided, with which processing of a dish container 102a can be achieved.

The processing equipment 200 for the dish container comprises a bottom plate 202 and an upper die core 206, wherein a plurality of first limiting pipes 202a are arranged on the upper side of the bottom plate 202, a second spring 204 is arranged in the first limiting pipes 202a, a vibrating plate 205 is arranged above the bottom plate 202, a second limiting pipe 205a is arranged on the lower side of the vibrating plate 205, the upper part of the second spring 204 is arranged in the second limiting pipe 205a, a die 207 is fixedly connected to the upper side of the vibrating plate 205, in particular, a plurality of fixing holes 205c are arranged on the vibrating plate 205, a plurality of third threaded counter bores 207a are arranged on one side of the die 207 facing downwards, a fastener such as a fastening screw and the like are used for penetrating through the fixing holes 205c and screwing into the third threaded counter bores 207a to fixedly connect the vibrating plate 205 with the die 207, a plurality of first guide posts 205b are arranged on the die 207, a die cavity is formed in one end of the upper side of the die 207 facing upwards, a first handle 206a is fixed on the upper side of the upper die core 206, a plurality of first guide holes 206c are arranged on the upper side of the upper die core 206, a plurality of first guide holes 206c are correspondingly arranged on the upper side of the upper die core 205b, a plurality of third threaded counter bores 208 are arranged on the upper side of the die core 208, a plurality of die cores 208 are abutted against the upper side of the die cavity 208, a plurality of die cavities 208 are formed on the lower side of the die cavity 208, and the upper side of the die core 208 is fixedly connected to the upper side of the die core 208 is arranged on the lower side of the upper side of the die core 208, and the lower side of the die core 208 is fixedly, which is fixedly connected to the upper side.

Further, a vibrating motor 203 is fixedly connected to the lower side of the vibrating plate 205 at one end of the lower mold core 208, and a balancing weight 201 having the same weight as the vibrating motor 203 is fixedly connected to the lower side of the vibrating plate 205 at the other end of the lower mold core 208.

Example 3

Referring to fig. 19 to 25, in order to provide a third embodiment of the present application, this embodiment is different from embodiment 1 and embodiment 2 in that this embodiment provides a method for processing a dish holder 102a using a processing apparatus 200 for a dish holder, which can implement processing of the dish holder 102a.

A method of processing a dish holder 102a using a processing apparatus 200 for a dish holder, comprising the steps of,

firstly, a plurality of second springs 204 are placed in a first limiting tube 202 a;

fixing the mold 207 to the vibration plate 205 using a first screw hole screwed into the vibration plate 205 and a second screw hole in the mold 207, the first screw through hole at the center of the vibration plate 205 and the second screw through hole at the center of the mold 207 being coaxial;

a plurality of second limiting pipes 205a on the lower side of the vibration plate 205 are sleeved at the upper end of the second spring 204;

the upper mold core 206 is sleeved into the first guide post 205b through the first guide hole 206c, so that the upper mold core 206 is tightly pressed on the mold 207;

inserting a wrench into the polygonal step 208a, rotating the wrench to enable the lower die core 208 to be screwed into the first threaded through hole and continue to be screwed into the second threaded through hole by utilizing the external thread 102b-1 on the periphery of the lower die core 208 until the upper surface of the lower die core 208 is in contact with the lower surface of the upper die core 206, and taking out the wrench;

applying casting material into the first casting cavity 209 through the casting hole 206 b;

the vibrating motor 203 is turned on, under the action of the second spring 204, the casting material in the first casting cavity 209 is compact and uniform, the occurrence of air holes is effectively avoided, the casting material is finished, the vibrating motor 203 is turned off, after a period of casting material shaping, the lower mold core 208 is reversely rotated out by using a wrench, the upper mold core 206 is taken out, and the cast dish container 102a is taken out.

The dish container is specially designed 102a in structure, and is processed by using a mechanical processing mode in the prior art, waste materials are wasted, and the processing efficiency is low, while the dish container 102a is processed through the design of the processing equipment 200 and the processing method of the dish container creatively, and in the processing process, the ceramic casting material is compacted and uniform by using the vibration motor 203, so that the generation of air holes is effectively avoided, and the dish container 102a is successfully processed, so that the processing is convenient and the efficiency is high.

Example 4

Referring to fig. 19 to 25, in order to achieve the fourth embodiment of the present application, the present embodiment is different from embodiments 1 to 3 in that it provides an apparatus for processing the heat conductor 102b, with which the processing of the heat conductor 102b can be achieved.

The equipment for processing the heat conductor 102b comprises a bottom die 302, a left die 303, a right die 301 and a processing die core 304, wherein a processing sinking groove 302c is formed in one side, facing upwards, of the center of the bottom die 302, a plurality of second guide posts 302a are arranged on the upper side of the bottom die 302 outside the processing sinking groove 302c, a plurality of first sliding grooves 303c are arranged on the left die 303, a plurality of second sliding grooves 301d are arranged on the right die 301, the left die 303 is inserted into the corresponding second guide posts 302a through the first sliding grooves 303c, the right die 301 is inserted into the corresponding second guide posts 302a through the second sliding grooves 301d, a first processing half hole 303b is formed in the center of the left die 303, a second processing half hole 301b which is identical to the first processing half hole 303b is formed in the center of the right die 301, the lower side of the left die 301 is abutted against the upper side of the bottom die 302, a plurality of second guide posts 304a are arranged on the upper side of the left die 301, a plurality of second handles 304a are arranged on the upper side of the processing die core 304, a plurality of second guide posts 304a are arranged on the processing 304, a plurality of outer edges 304b are arranged on the processing half holes 304b corresponding to the second guide posts 304a, the outer edges 304b are formed in the shape of the second die core 304b, and the outer edges 304b are formed in the shape of the second die core 304b, which are identical to the second processing half holes 304b, and the outer edges 304b are formed on the side of the die core 304b, and the outer edges 304b of the second guide holes 304b are formed in the processing half holes 304b, and the processing half holes 304b are formed in the processing half holes, and processing half holes are processed by processing half holes of the processing half holes and are correspondingly.

In order to further facilitate the positioning of the left die 303 and the right die 301 during die assembly, the bottom die 302 on both sides of the outer edge center of the processing sink 302c is provided with a limiting column 302b, one side of the left die 303, which is opposite to the right die 301, is provided with a left positioning half hole 303d corresponding to the limiting column 302b, one side of the right die 301, which is opposite to the left die 303, is provided with a right positioning half hole 301c corresponding to the limiting column 302b, and when the left die 303 and the right die 301 are combined together, the left positioning half hole 303d and the right positioning half hole 301c just surround the corresponding limiting column 302b.

To further facilitate mold closing and parting, a left handle 303a is provided on the side of the left mold 303 away from the right mold 301, and a right handle 301a is provided on the side of the right mold 301 away from the left mold 303.

Example 5

Referring to fig. 19 to 25, in order to fifth embodiment of the present application, this embodiment is different from embodiments 1 to 4 in that this embodiment provides a method of processing a heat conductor 102b using a processing apparatus 300 of a heat conductor, which can realize the processing of the heat conductor 102b.

A method of processing the heat conductor 102b using the processing apparatus 300 for heat conductor, comprising the steps of,

the left die 303 is sleeved into the second guide post 302a through the first sliding groove 303c, the right die 301 is sleeved into the second guide post 302a through the second sliding groove 301d, the left handle 303a and the right handle 301a are pushed to enable the left die 303 and the right die 301 to be clamped, and the limiting post 302b limits the left die 303 and the right die 301;

holding the second handle 304a to sleeve the processing mold core 304 on the second guide post 302a, so that the processing mold core 304 is abutted against the upper sides of the left mold 303 and the right mold 301 which are combined together;

the molten casting material is die-cast into the second casting cavity 305 through the die-casting hole 304b, and is exhausted through the air outlet hole 304 c;

after the casting is finished and cooled, the processing mold core 304 is opened, and the left mold 303 and the right mold 301 are pulled outward by the left handle 303a and the right handle 301a, so that the die-cast heat conductor 102b is taken out.

The processing equipment 300 and the processing method of the heat conductor realize the processing of the heat conductor 102b, and are convenient to process and high in efficiency.

It should be noted that the above embodiments are only for illustrating the technical solution of the present application and not for limiting the same, and although the present application has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that the technical solution of the present application may be modified or substituted without departing from the spirit and scope of the technical solution of the present application, which is intended to be covered in the scope of the claims of the present application.

Claims (10)

1. A dish heat preservation device, its characterized in that: which comprises the steps of (a) a step of,

the device comprises a heat-preserving furnace body (101), wherein an appliance placing cavity (101 b) is formed in one upward end of the heat-preserving furnace body (101), a control bin (101 a) is formed in one downward end of the heat-preserving furnace body (101), and a furnace chamber (101 d) is formed in the heat-preserving furnace body (101) between the control bin (101 a) and the appliance placing cavity (101 b);

the heat-preserving heating connecting unit (103), the heat-preserving heating connecting unit (103) comprises a furnace chamber cover plate (103 g) and a heating shell (103 d), the heating shell (103 d) is connected with a heating tube (103 b) and a first spring (103 c), the heating shell (103 d) is connected into the heat-preserving furnace body (101) through the furnace chamber (101 d), the furnace chamber cover plate (103 g) is fixedly connected into the heat-preserving furnace body (101) at the lower side of the furnace chamber (101 d), and the lower side of the first spring (103 c) is abutted against the furnace chamber cover plate (103 g);

hold heat conduction unit (102), hold heat conduction unit (102) including having dish container (102 a) of opening (102 a-2) up, dish container (102 a) one end threaded connection down has heat conduction ware (102 b), the upside of heat conduction ware (102 b) flushes with the downside of opening (102 a-2), dish container (102 a) are laid chamber (101 b) through the utensil and are supported on heat preservation furnace body (101), the upside of shell (103 d) generates heat is contradicted to one side down in heat conduction ware (102 b).

2. The dish warming device of claim 1, wherein: the heat preservation heating connection unit (103) further comprises a control bin cover plate (103 h) fixedly connected with the heat preservation furnace body (101) and arranged at the lower side of the control bin (101 a), a control circuit board (103 i) and a power supply (103 f) are connected to the upper side of the control bin cover plate (103 h), a first lead hole (103 g-1) and a second lead hole (103 g-2) are formed in the furnace chamber cover plate (103 g), an electric wire (103 e) is connected to the heating tube (103 b), the lower end of the electric wire (103 e) penetrates through the first lead hole (103 g-1) and the power supply (103 f) to be connected, a temperature sensor (103 a) is fixedly connected to the heating shell (103 d) close to the heating tube (103 b), a data wire (103 j) is connected to the temperature sensor (103 a), and the data wire (103 j) penetrates through the second lead hole (103 g-2) and the control circuit board (103 i) to be connected.

3. A dish warming device as claimed in claim 1 or claim 2, wherein: the dish contains ware (102 a) towards one end open there is step hole (102 a-1), cover sealing washer (102 c) on heat conduction ware (102 b), the periphery of heat conduction ware (102 b) lower part is equipped with external screw thread (102 b-1), heat conduction ware (102 b) are through step hole (102 a-1) threaded connection in dish containing ware (102 a) lower part, and heat conduction ware (102 b) compress tightly sealing washer (102 c) on dish containing ware (102 a).

4. A device for processing a dish holder as claimed in claim 3, wherein: the die comprises a bottom plate (202) and an upper die core (206), wherein a plurality of first limit pipes (202 a) are arranged on the upper side of the bottom plate (202), a second spring (204) is arranged in the first limit pipes (202 a), a vibrating plate (205) is arranged above the bottom plate (202), a second limit pipe (205 a) is arranged on the lower side of the vibrating plate (205), a die (207) is fixedly connected to the upper side of the second spring (204) in the second limit pipes (205 a), a plurality of first guide posts (205 b) are arranged on the die (207), a die cavity is formed in one end of the die (207) facing upwards, a plurality of first guide holes (206 c) corresponding to the first guide posts (205 b) are arranged on the upper die core (206), the lower side of the upper die core (206) is in contact with the upper side of the die (207), a plurality of die cores (206) are in contact with each other through the first guide holes (206 c), the upper die cores (208) are in contact with each other on the upper side of the die (205), a plurality of die cores (208) are in contact with each other on the outer edge of the upper die cavity (206) which is formed on the outer side of the lower side of the die cavity (208), the dish container (102 a) is processed.

5. The processing apparatus for a dish holder as claimed in claim 4, wherein: the vibrating motor (203) is fixedly connected to the lower side of the vibrating plate (205) at one end of the lower die core (208), and the balancing weight (201) with the same weight as the vibrating motor (203) is fixedly connected to the lower side of the vibrating plate (205) at the other end of the lower die core (208).

6. An apparatus for processing a heat conductor as claimed in claim 3, wherein: the die comprises a bottom die (302), a left die (303), a right die (301) and a processing die core (304), wherein a processing sinking groove (302 c) is formed in one side of the bottom die (302) with the center upwards, a plurality of second guide posts (302 a) are arranged on the upper side of the bottom die (302) outside the processing sinking groove (302 c), a plurality of first sliding grooves (303 c) are arranged on the left die (303), a plurality of second sliding grooves (301 d) are arranged on the right die (301), the left die (303) is inserted into a corresponding second guide post (302 a) through the first sliding grooves (303 c), the right die (301) is inserted into a corresponding second guide post (302 a) through the second sliding grooves (301 d), a first processing half hole (303 b) is formed in the center of the left die (303), a second processing half hole (301 b) which is identical to the first processing half hole (303 b) is formed in the center of the right die (301), a plurality of second sliding grooves (301 d) are arranged on the right die (301), the left die (301) is abutted against the upper side of the bottom die (302), the left die (301) is abutted against the upper side of the corresponding second guide post (302), the right die (301) is inserted into the corresponding second guide post (302 a) through the second guide post (302 d) and the corresponding second guide post (304 a) are arranged on the right die (301 d) side, the die casting device is characterized in that a die casting hole (304 b) and an air outlet hole (304 c) are formed in the processing die core (304), and a second casting cavity (305) with the same shape as the heat conductor (102 b) is formed among the outer edge of the processing die core (304), the outer edge of the first processing half hole (303 b), the outer edge of the second processing half hole (301 b) and the outer edge of the processing sinking groove (302 c) at the lower side of the die casting hole (304 b), so that the heat conductor (102 b) is processed.

7. The processing apparatus of the heat conductor as claimed in claim 6, wherein: limiting columns (302 b) are arranged on bottom dies (302) on two sides of the outer edge center of a machining sinking groove (302 c), left positioning half holes (303 d) corresponding to the limiting columns (302 b) are formed in one side, which is arranged on the left die (303) opposite to the right die (301), of the right die (301), right positioning half holes (301 c) corresponding to the limiting columns (302 b) are formed in one side, which is arranged on the right die (301) opposite to the left die (303), of the left die (303), and when the left die (303) and the right die (301) are combined together, the left positioning half holes (303 d) and the right positioning half holes (301 c) just encircle the corresponding limiting columns (302 b).

8. The processing apparatus of the heat conductor as claimed in claim 6, wherein: a left handle (303 a) is arranged on one side, far away from the right die (301), of the left die (303), and a right handle (301 a) is arranged on one side, far away from the left die (303), of the right die (301).

9. A method of processing a dish holder using the apparatus of claim 4, wherein: comprises the steps of,

firstly, a plurality of second springs (204) are put into a first limiting tube (202 a);

fixing the mold (207) on the vibration plate (205) by using a first threaded hole screwed into the vibration plate (205) and a second threaded hole on the mold (207), wherein the first threaded through hole at the center of the vibration plate (205) and the second threaded through hole at the center of the mold (207) are coaxial;

a plurality of second limiting pipes (205 a) at the lower side of the vibrating plate (205) are sleeved at the upper ends of the second springs (204);

the upper mold core (206) is sleeved into the first guide pillar (205 b) through the first guide hole (206 c), so that the upper mold core (206) is tightly pressed on the mold (207);

screwing the lower die core (208) into the first threaded through hole and continuing to screw into the second threaded through hole by utilizing the external threads (102 b-1) on the periphery of the lower die core (208) until the upper surface of the lower die core (208) is in contact with the lower surface of the upper die core (206);

applying casting material into the first casting cavity (209) through the casting material hole (206 b);

and opening the vibrating motor (203), compacting and homogenizing the casting materials in the first casting cavity (209) under the action of the second spring (204), closing the vibrating motor (203), rotating out the lower mold core (208) after casting materials are molded for a period of time, taking out the upper mold core (206), and taking out the cast dish container (102 a).

10. A method of processing a heat conductor using the apparatus of claim 6, wherein: comprises the steps of,

the left die (303) is sleeved into the second guide post (302 a) through the first sliding groove (303 c), the right die (301) is sleeved into the second guide post (302 a) through the second sliding groove (301 d), the left die (303) and the right die (301) are pushed to be clamped, and the left die (303) and the right die (301) are limited by the limiting post (302 b);

sleeving a processing mold core (304) on the second guide post (302 a), so that the processing mold core (304) is abutted against the upper sides of the left mold (303) and the right mold (301) which are combined together;

casting the molten casting material into a second casting cavity (305) through a casting hole (304 b), and exhausting by using an air outlet hole (304 c);

after the casting material is cooled, the processing mold core (304) is started, the left mold (303) and the right mold (301) are pulled outwards, and the die-cast heat conductor (102 b) is taken out.