CN104913509B

CN104913509B - Method for manufacturing temperature-adjustable timing running hot water steam device

Info

Publication number: CN104913509B
Application number: CN201510316460.XA
Authority: CN
Inventors: 章祖文
Original assignee: Individual
Current assignee: Individual
Priority date: 2015-06-11
Filing date: 2015-06-11
Publication date: 2020-07-07
Anticipated expiration: 2035-06-11
Also published as: CN104913509A

Abstract

The invention discloses a temperature-adjustable timing tap water steam device, which comprises A-type, B-type, C-type, D-type and E-type temperature-adjustable timing tap water steam devices, and is characterized in that: the electric heating water heater is characterized in that the electric heating water heater is provided with a shell, hot water steam elements consisting of a bent tap water pipe, an electric heating pipe and an outer-wrapped pouring heat conductor, a tap water inlet pipe, a hot water pipe, a steam pipe and a switch are arranged, a pressure-regulating constant-temperature control box, a digital voltmeter, a thermometer, a timing meter, an indicator lamp, a potentiometer, a binding post and a hook are arranged, a power supply and a water source are connected, voltage and temperature are regulated, and the electric heating water heater can obtain needed hot water steam after being preheated for three minutes, so that the electric heating water heater is.

Description

Method for manufacturing temperature-adjustable timing running hot water steam device

Technical Field

The invention relates to a method for manufacturing a hot water device, in particular to a method for manufacturing a temperature-adjustable and timing tap hot water steam device.

Technical Field

At present, the discontinuous hot water steam device is provided with a kettle, a pot, a barrel and the like which are heated by flame or electricity, and the discontinuous hot water steam device is provided with a gas water heater, the former is inconvenient to be discontinuous in a two-character shape, and the volume of the kettle, the pot and the barrel is large; the latter is uninterrupted, but the water yield is low and the gas consumption is high. The small steam device is a pot and a steamer, and has the disadvantages of high fuel consumption and low steam pressure.

Disclosure of Invention

The invention aims to provide a temperature-adjustable timing running hot water steam device which can uninterruptedly change running cold water into running hot water steam and is convenient for people's life.

The purpose of the invention is realized as follows:

a method for manufacturing a temperature-adjustable timing tap water steam device comprises a dry-heating electric heating tube, a heating aluminum disc, an iron disc, a shell, various pipelines and elbows, and is characterized in that: the invention is composed of a hot water steam element, a pressure-regulating and temperature-regulating timing box, a shell, a panel, a hook, a cold water inlet pipe and a switch, a hot water outlet pipe and a switch, a steam outlet pipe and a switch, and a safety valve, wherein the different temperature-regulating and timing running hot water steam devices are the same except that the hot water steam element is different; five kinds of hot water steam elements A1, B1, C1, D1 and E1 are available, and five kinds of temperature-adjustable timing tap water steam devices A, B, C, D, E are available. The hot water steam element A1 is composed of a ball-embedded plane square-circle spiral stainless steel tap water pipe, electric heating pipes welded on the inner and outer rings, and iron shells coated on two wings and provided with mounting holes, wherein the tap water pipe vertically led out from the middle lower part of the plane and the tap water pipe vertically led out from the middle plane of the lower end of the plane are respectively connected with a tap water inlet pipe, a hot water outlet pipe and a steam outlet pipe through an internal thread pipe, a baffle plate, a straight pipe and a tee joint, and the electric heating pipes led out from the upper part and the lower part of the plane are connected with an output power supply of a; the hot water steam element B1 is composed of a stainless steel tap water pipe with a built-in ball bearing with a narrow square round spiral pipe section, an electric heating pipe welded in the spiral pipe, and an outer iron casing with mounting holes on two wings, wherein the tap water pipe led out from the upper end and the lower end of the spiral pipe is respectively connected with a tap water inlet pipe, a hot water outlet pipe and a steam outlet pipe through an internal thread pipe, a baffle plate, a straight pipe and a tee joint; the electrothermal tube that is drawn from the upper portion of the solenoid is linked with the output power of the pressure-regulating and temperature-regulating timing box, the hot water vapor component C1 is formed by stainless steel running water pipe with built-in ball and round solenoid-shaped cross section, electrothermal tube welded in the solenoid, and outer iron casing with mounting holes on both wings, the running water pipe that is drawn from the upper and lower ends of the solenoid is connected with the running water inlet pipe, the hot water outlet pipe and the steam outlet pipe respectively through an internal thread pipe, a baffle plate and a straight pipe, the electrothermal tube that is drawn from the upper portion of the solenoid is linked with the output power of the pressure-regulating and temperature-regulating timing box; the hot water steam element D1 is made by coiling a stainless steel pipe with three-way pipes welded at two ends and an electric heating pipe which is internally provided, slightly long and evenly welded with a positioning wafer with holes vertical to the axis into a spiral pipe, then welding two fixed iron sheets with holes on the upper and lower same planes and internally provided with balls, the side pipes of the upper and lower three-way pipes are respectively connected with a water inlet pipe, a hot water outlet pipe and a steam outlet pipe through an internal thread pipe, a baffle, a straight pipe and a tee joint, and the electric heating pipe in the straight pipe of the upper and lower tee joints is connected with an output power supply of a pressure-regulating and temperature; the hot water steam element E1 is composed of an inner layer and an outer layer which are provided with induction coils at the middle layer and have circular sections, a solenoid-shaped magnet-absorbable stainless steel water pipe, a built-in magnet-absorbable stainless steel ball, a power frequency or intermediate frequency power supply and a high-temperature glass heat insulation box, wherein the built-in ball double-layer sections are circular, a solenoid-shaped tap water pipe and the induction coils are arranged in the high-temperature glass heat insulation box, the upper end of the built-in ball double-layer sections are respectively connected with a tap water pipe, a hot water outlet pipe and a steam outlet pipe through top layer glass, a shell mounting hole, a baffle plate and a straight pipe, the induction coils are connected with the power frequency or intermediate frequency power supply, and the power frequency; the pressure regulating and temperature regulating timing box is internally provided with a module with a cooling plate of a voltage-reducing bidirectional thyristor pressure regulating circuit in sequence, and a temperature regulating timing circuit board consisting of an NMOS tube, a triode, a photoelectric coupler, a thermistor, a fixed temperature switch, a timing switch, a gear shifting switch, a resistor and a potentiometer. The hot water steam element, the tap water cooling plate and the pressure and temperature regulating timing box are arranged in the shell, and a panel of the shell is provided with a voltage, temperature and time digital display meter and an adjusting knob.

The invention is obtained by improving the traditional electric heating, heating plate and gas water heater, and has the following characteristics:

1. the speed of changing cold water into hot water vapor is high and the amount is sufficient;

2. the large water storage tank is not needed, the area and the volume of the hot water steam element are not large, the hot water steam element is not heavy, and the hot water steam element can be hung at a high position or supported at the high position by a bracket;

3. the temperature can be preset, the height can be adjusted, and the digital display can be realized; the output voltage of the voltage-reducing silicon controlled voltage regulating circuit can be adjusted within an allowable voltage range.

Drawings

FIG. 1a is a schematic external view of a hot water vapor cell A1 a;

FIG. 1b is a diagram showing the positional relationship between the stainless steel tube A1a and the electrothermal tubes a2a and a2b in A1 a;

FIG. 1c is a schematic structural diagram of the ball a1b, the baffle a1c1, the a1c2, the internally threaded tube a1d1, the a1d2, the straight tube a1e1, the a1e2 and the short copper tube a1f in A1;

FIG. 1d is a schematic structural view of a mold a3 for casting A1a heat-conducting shell;

FIG. 1e is a diagram showing the positional relationship among a hot water steam component A1, a casing A2a, A2b, a panel A2c, a hook A2d, a water inlet pipe A3a, a switch A3b, a cooling plate A3c, TYTVDSH, a hot water pipe A4a, a switch A4b, a tee A4c, a steam pipe A5a, a switch A5b and a safety valve A5 c;

FIG. 2a is an external view of the hot water steam component B1 a;

FIG. 2B is a diagram showing the positional relationship between the stainless steel tube B1a and the electrothermal tubes B2a and B2B in B1;

FIG. 2c is a schematic structural diagram of a ball b1b, a baffle b1c1, a baffle b1c2, an internally threaded tube b1d1, a tube b1d2, a straight tube b1e1, a tube b1e2 and a short copper tube b1 f;

FIG. 2d is a schematic view of a mold B3 for casting a heat-conducting shell of a hot water vapor component B1a and a bottom plate;

FIG. 2e is a diagram showing the positional relationship among the hot water steam unit B1, the housings B2a, B2B, the panel B2c, the hook B2d, the water inlet pipe B3a, the switch B3B, the cooling plate B3c, TYTVDSH, the hot water pipe B4a, the switch B4B, the tee joint B4c, the steam pipe B5a, the switch B5B and the safety valve B5 c;

FIG. 3a is an external view of the hot water steam component C1 a;

FIG. 3b is a diagram showing the positional relationship between the stainless steel water tube C1a and the electrothermal tube C2a1-C2a4 in C1;

FIG. 3c is a schematic structural view of a ball c1b, a baffle c1c1, a baffle c1c2, an internally threaded tube c1d1, a tube c1d2, a straight tube c1e1, a straight tube c1e2 and a short copper tube c1 f;

FIG. 3d is a schematic structural view of a mold C3 for casting a heat-conducting shell of a hot water vapor component C1 a;

FIG. 3e is a diagram showing the positional relationship among the hot water steam unit C1, the housings C2a, C2b, the panel C2C, the hook C2d, the water inlet pipe C3a, the switch C3b, the cooling plate C3C, TYTVDSH, the hot water pipe C4a, the switch C4b, the tee C4C, the steam pipe C5a, the switch C5b and the safety valve C5C;

FIG. 4a is an external view of the hot water steam unit D1;

FIG. 4b is a diagram showing the positional relationship among the stainless steel tube D1a, the electrothermal tube D2a1, the three-way tube D1g, the three-way tube D1h, the equidistant circular plate D2a2 with holes and the head closing plate D2a3 in the hot water steam unit D1;

FIG. 4c is a schematic structural diagram of a ball d1b, a baffle d1c1, a baffle d1c2, an internally threaded tube d1d1, a tube d1d2, a straight tube d1e1, a straight tube d1e1, a straight tube d1e2 and a short copper tube d1 f;

FIG. 4D is a diagram showing the positional relationship among the hot water steam unit D1, the housings D2a, D2b, the panel D2c, the hook D2D, the water inlet pipe D3a, the switch D3b, the cooling plate D3c, TYTWDSH, the hot water pipe D4a, the switch D4b, the tee D4c, the steam pipe D5a, the switch D5b and the safety valve D5 c;

FIG. 5a is an external view of the hot water steam element E1 a;

FIG. 5b is a diagram showing the positional relationship between the stainless steel tube E1a and the heating induction coil E2a in the hot water steam unit E1 a;

FIG. 5c is a schematic structural view of a ball e1b, a baffle e1c1, an e1c2, an internally threaded tube e1d1, an e1d2, a straight tube e1e1, an e1e2 and a short copper tube e1 f;

FIG. 5d1a is a schematic front view of positioning slots e3a1a and e3a2a for ceramic or aluminum glass at the upper and lower bottoms of the high temperature glass incubator;

FIG. 5d1b is a schematic view of the reverse structure of the positioning slots e3a1a and e3a2a for the ceramic or aluminum glass at the upper and lower bottoms of the high temperature glass incubator;

FIG. 5d2 is a schematic structural view of four pillars e3b1a-e3b4a of glass positioning slots perpendicular to each other in a high temperature glass incubator made of porcelain or drawn aluminum;

FIG. 5d3 is a schematic structural view of stainless steel glass positioning slots e3a1b and e3a2b at the upper and lower bottoms of the high temperature glass incubator;

FIG. 5d4 is a schematic structural view of a four-column stainless steel glass positioning clip groove e3b1b-e3b4b of a high temperature glass incubator;

FIG. 5d5 is a schematic structural view of positioning slots e3a1c and e3a2c for welding and drawing aluminum glass at the upper and lower undercuts of a high temperature glass incubator;

FIG. 5d6 is a schematic structural view of stainless steel base e3c, porcelain washer e3d and stainless steel perforated base plate e3e of the high temperature glass incubator;

FIG. 5d7 is a diagram showing the positional relationship among the hot water steam unit E1, the housings E2a, E2b, the panel E2c, the hook E2d, the water inlet pipe E3a, the switch E3b, the cooling plate E3c, TYTVDSH, the hot water pipe E4a, the switch E4b, the tee E4c, the steam pipe E5a, the switch E5b and the safety valve E5 c;

FIG. 6a1 is a schematic diagram of the shell structure of shell A2;

FIG. 6a2 is a schematic diagram of the shell structure in shell B2;

FIG. 6a3 is a schematic diagram of the shell structure of shell C2;

FIG. 6a4 is a schematic diagram of the structure of the middle shell of outer shell D2;

FIG. 6a5 is a schematic diagram of the shell structure in shell E2;

FIG. 6b1 is a schematic structural diagram of the rear shell of Shell A2;

FIG. 6B2 is a structural diagram of the rear shell of shell B2;

FIG. 6b3 is a structural diagram of the rear shell of shell C2;

FIG. 6b4 is a structural diagram of the rear shell of the housing D2;

FIG. 6b5 is a structural diagram of the rear shell of the shell E2;

FIG. 6c1 is a schematic structural view of a panel of casing A2;

FIG. 6c2 is a schematic structural view of a panel of a housing B2;

FIG. 6C3 is a schematic structural view of a panel of the case C2;

FIG. 6c4 is a schematic structural view of a panel of housing D2;

FIG. 6c5 is a schematic structural view of a panel of the housing E2;

FIG. 6d is a schematic structural view of a main shell of a porous angle iron shell C2;

FIG. 6e is a schematic view of a perforated angle iron housing C2 panel configuration;

FIG. 7a is a schematic structural diagram of a main box TYTHDSH 1 of the pressure-regulating and temperature-regulating timing box;

FIG. 7b is a schematic structural view of a front panel TYTWDSH2 of the pressure-regulating and temperature-regulating timing box;

FIG. 7c is a schematic structural view of a rear panel TYTWDSH3 of the pressure-regulating and temperature-regulating timing box;

FIG. 7d is a schematic diagram of a modular cooling plate structure in the pressure and temperature regulating timing box;

FIG. 8a is a schematic structural diagram of a voltage-sequentially-dropping bidirectional thyristor voltage-regulating circuit YCJYSXKKGTYDL 1;

FIG. 8b is a schematic structural diagram of a voltage-sequentially-dropping bidirectional thyristor voltage-regulating circuit YCJYSXKKGTYDL 2;

fig. 8c is a schematic diagram of a local circuit structure of the sequential step-down bidirectional thyristor voltage-regulating circuit YCJYSXKKGTYDL1 obtained by locally modifying the sequential step-down bidirectional thyristor voltage-regulating circuit YCJYSXKKGTYDL 3;

fig. 8d is a schematic diagram of a local circuit structure of the sequential step-down bidirectional thyristor voltage regulating circuit YCJYSXKKGTYDL2 obtained by locally modifying the sequential step-down bidirectional thyristor voltage regulating circuit YCJYSXKKGTYDL 4;

FIG. 8e is a schematic diagram of the TWDL structure of the temperature control circuit;

fig. 8f is a schematic structural diagram of a power frequency transformer e2 b;

FIG. 8g is a schematic circuit diagram of a circuit structure of a secondary side of a power frequency transformer e2b connected with a load e2c through a shift switch K3 and TYTVDSH;

FIG. 8h is a structural diagram of a non-polar capacitor C3;

fig. 8i is a schematic structural diagram of an IGBT ac voltage regulator circuit in patent 2011101897839.

Detailed Description

The present invention will be described in further detail with reference to the following examples and drawings.

Example 1: the manufacturing method of the A-type temperature-adjustable timing tap water steam device comprises the following steps:

1. manufacturing a planar spiral stainless steel tap water pipe a1a left-falling and dry-burn electric heating tubes a2a and a2b, wherein two ends of the bottom of the planar spiral stainless steel tap water pipe are circular, the middle of the planar spiral stainless steel tap water pipe is rectangular, the semicircular central plane of the bottom of the outer end of the planar spiral stainless steel tap water pipe is led out, and the inner end of the planar spiral stainless steel tap water pipe is led; a2a is tightly attached to the inside of a1a, a2b is tightly sleeved on the outside of a1a, the distance between the wiring ends is 5-10 cm, and the heights of the vertical upward bent parts of the two ends of a2a and a2b are about 5 cm;

2. making two square-round bottoms, two ends of which are vertically led out upwards and can be connected with electric heating tubes a2a and a2b for dry burning; a2a is tightly attached to the inside of a1a, a2b is tightly sleeved on the outside of a1a, the distance between the wiring ends is 5-10 cm, and the heights of the vertical upward bending parts of the two ends of a2a and a2b are about 5 cm;

3. manufacturing stainless steel balls a1b which can be poured into and poured out of the spiral pipe a1a, stainless steel baffles a1c1 and a1c2 which have small holes with the same diameter at two ends and can not pass through the balls after being washed with water, and internally-threaded pipes a1d1 and a1d2 which have baffles at two ends and are slightly shorter than 4 cm and internally-arranged non-thick and non-thin straight pipes a1e1 and a1e 2; a1b, A1c1, A1c2, A1d1, A1d2, A1e1 and A1e2 are combined into a hot water steam element A1 b;

4. the mold for manufacturing the heat-conducting shell a3 of the hot water vapor element A1a is as follows: the thickness of the a3 shell is about 5 mm, besides the a2a, a2b and a1a parts can be wrapped, the bottoms of the two sides of the long side are also provided with two wings with mounting holes, the thickness is about 5 mm, and the two wings with mounting holes can be replaced by iron sheets with welded holes;

5. a2a, a2b and A1a are welded in the same plane, four terminals of an electric heating tube are tied by soft ropes, the four terminals are hung in a die and are leveled, molten iron is injected, and the hot water steam element A1a is obtained after cooling and demoulding, wherein A1a and A1b are combined into a hot water steam element A1;

6. making a shell A, wherein a middle shell A2 of the shell A is provided with a pipe inlet hole, a pipe inlet hole and a pipe outlet hole below, a front shell of the shell A is a panel A2, the A2 is provided with an instrument, a potentiometer, a bolt, a switch and an indicator lamp mounting hole, a rear shell A2 of the shell A is provided with a mounting hole and a hook hole, a hot water steam element A1 and a hook A2 are simultaneously arranged inside and outside the rear shell A2, a glass fiber heat preservation layer is added on the A1, a proper amount of balls A1 are arranged in the A1, two ends of the A1 are respectively provided with a baffle plate A1c and A1c, the baffle plate A1d and the straight pipe A1e are connected with a water inlet pipe A3 and a switch A3 through internal threads, the straight pipe A1d and the straight pipe A1e and A1e, the straight pipe A3 is connected with the tee joint A4, the hot water pipe A4 and the switch A4 through the steam pipe A5, the steam pipe A5 is connected with the A4, the switch A5, the cooling plate A3, a constant temperature circuit box is arranged on the A3 during pressure regulation, the DSH is connected with a TYH output end of a, the thermometer measurement and control end, the fixed temperature switch Kt 1-Kt 4 and the thermistor Rt are adhered to a3, the terminals of Rt, Kt 1-Kt 4, the potentiometers W1-W5, the timing switch K1 and the gear shift switch K2 are all connected with an internal circuit of TYTDSH through bolts, the voltmeter, the thermometer, the timing switch, the gear shift switch, the potentiometers, the indicator light and the wiring terminals are all arranged on the panel A2c, and cast iron, stainless steel tubes and steel balls are replaced by cast aluminum, copper tubes, short and small copper tubes and iron rings correspondingly; cast iron or replaced by sealed aluminum nitride or graphite powder.

An A-shaped temperature-adjustable timing tap hot water steam device is made.

Example 2: method for manufacturing B-type temperature-adjustable timing tap water steam device

1. Manufacturing a solenoid-shaped stainless steel tap water pipe b1a with an external thread interface, wherein two ends of the section of the solenoid-shaped stainless steel tap water pipe b1 are circular, the middle of the solenoid-shaped stainless steel tap water pipe b1 is narrow and rectangular, two ends of the solenoid-shaped stainless steel tap water pipe b are vertically bent upwards and downwards, the length of the straight pipe b1a is 6-12 meters of a 4-minute stainless steel pipe, b1a is vertical or horizontal, two ends of the solenoid-shaped stainless steel tap water pipe b are vertically led out upwards and downwards, two parts without threads are respectively 5 centimeters, parts with;

2. manufacturing stainless steel balls B1B, combining water passing ball baffles B1c1, B1c2, internally threaded pipes B1d1, B1d2 and internally-arranged 4 cm short and loose-proof straight pipes B1e1 and B1e2, B1B, B1c1, B1c2, B1d1, B1d2, B1e1 and B1e2 into a hot water steam element B1B;

3. manufacturing U-shaped electric heating tubes b2a1 and b2a2 with two ends bent vertically upwards and capable of being connected in a dry-burning mode, wherein the length of each U-shaped electric heating tube is equal to the height of the spiral tube plus 5-10 cm;

4. the mould for manufacturing the B1a heat-conducting shell B3 is about 5 mm thick, two wings with mounting holes are arranged at the bottoms of two sides of the long side except for surrounding B1a, B2a1 and B2a2, and the thickness is about 5 mm and is parallel to the center of the spiral pipe;

5. welding U-shaped electric heating tubes B2a1 and B2a2 on the inner wall of B1a in parallel, tying four terminals of the electric heating tubes by soft ropes, hanging the electric heating tubes into a die, leveling, injecting molten iron, and cooling to obtain a hot water steam element B1 a; b1a and B1B are combined into a hot water steam element B1;

6. making a shell B, wherein a middle shell B2 of the shell B is provided with a pipe inlet hole, a pipe inlet hole and a pipe outlet hole below, a front shell of the shell B is a panel B2, the B2 is provided with an instrument, a potentiometer, a bolt, a switch and an indicator lamp mounting hole, a rear shell B2 of the shell B is provided with a mounting hole and a hook hole, a hot water steam element B1 and a hook B2 are simultaneously arranged inside and outside the rear shell B2, a glass fiber heat preservation layer is added on the B1, a proper amount of balls B1 are arranged in the B1, two ends of the B1 are respectively provided with a baffle plate B1c and a baffle plate B1c, the baffle plate B1c is connected with a straight pipe B1d and a straight pipe B1e, the straight pipe B1e through an internal thread pipe B3 d and a switch B3, the lower end of the straight pipe B4 is connected with a tee joint B4, the hot water pipe B4 and the switch B4, the steam pipe B5 is connected with the B4 through a steam pipe B5, the steam pipe B3, the cooling plate B3 is connected with a connecting terminal of the TYH circuit box, the TYH is arranged on the power supply box when the voltage regulating is fixed, the TYH, the thermometer measurement and control end, the fixed temperature switch Kt 1-Kt 4 and the thermistor Rt are adhered to B3, the Rt, the fixed temperature switch Kt 1-Kt 4, the potentiometer W1-W5, the timing switch K1 and the wiring terminal of the shift switch K2 are all connected with an internal circuit of TYTVDSH through bolts, the voltmeter, the thermometer, the timing switch, the shift switch, the potentiometer, the indicator light and the wiring terminal are all arranged on the panel B2c, and cast iron, stainless steel tubes and steel balls are replaced by cast aluminum, copper tubes, short copper tubes and iron rings correspondingly; cast iron or replaced by sealed aluminum nitride or graphite powder.

Embodiment 3. method for manufacturing C-type temperature-adjustable timing tap water steam device

1. Manufacturing stainless steel screwed pipe-shaped tap water pipes c1a and c1a with round sections and two ends which are vertically bent up and down respectively and provided with external threaded interfaces, or vertically or horizontally placing the stainless steel screwed pipe-shaped tap water pipes c1a and c1 a; the bent parts of the upper and lower unthreaded parts at the two ends are about 5cm long respectively, and the parts with the upper and lower external threads are about 5cm long respectively;

2. making U-shaped electric heating tubes c2a1-c2a4 with two ends bent upwards vertically and capable of being connected for dry burning;

3. manufacturing stainless steel balls c1b which can be poured into and poured out of a stainless steel pipe, end baffles c1c1 and c1c2 which can not pass through the stainless steel pipe after being washed with water, internal threaded pipes c1d1 and c1d2 and built-in slightly short and loose straight pipes c1e1 and c1e 2; c1b, C1C1, C1C2, C1d1, C1d2, C1e1 and C1e2 are combined into a hot water steam element C1 b;

4. manufacturing a mold for pouring a heat-conducting shell C3 of a hot water steam element C1a, wherein the thickness of C3 is about 5 mm, two wings with mounting holes are arranged at the bottoms of two sides except for surrounding C1a and C2a1-C2a4, and the two wings are parallel to a central line;

5. uniformly and vertically sticking the electrothermal tube c2a1-c2a4 on the inner wall of the spiral tube c2a, and welding; tying the four electric heating tube terminals by using soft ropes, hanging the electric heating tube terminals into a mold, leveling the electric heating tube terminals, injecting molten iron, and cooling to obtain a hot water vapor element C1 a; c1a and C1b are combined into hot water steam elements C1 and C1a or consist of C1a with C2a1-C2a4 welded on the inner wall, a preheating water cylinder C1f with sealing heads and 4-branch threaded pipes which are arranged in the preheating water cylinder and tightly attached to two ends, an iron sheet with holes welded on the outer part and heat-insulating glass filaments;

6. making a shell C, wherein a middle shell C2 of the shell C is provided with a pipe inlet hole, a pipe inlet hole and a pipe outlet hole below, a front shell of the shell C is a panel C2, the C2 is provided with an instrument, a potentiometer, a bolt, a switch and an indicator lamp mounting hole, a rear shell C2 of the shell C is provided with a mounting hole and a hook hole, a hot water steam element C1 and a hook C2 are simultaneously arranged inside and outside the rear shell C2, a glass fiber heat preservation layer is added on the C1, a proper amount of balls C1 are arranged in the C1, two ends of the C1 are respectively provided with a baffle plate C1C and a baffle plate C1C, and are respectively connected with a tap water pipe C3 and a switch C3 through inner thread pipes C1d, a straight pipe C1e and C1e, a tee joint C4 is arranged below the tap water pipe C4, the hot water pipe C4 and the switch C4, a steam pipe C5 is respectively connected with the C4, a safety valve C5 and the switch C5, a cooling plate C3 is arranged on the C3, a constant temperature circuit box is arranged on the TYH 3 when pressure regulating is fixed, a TYH is connected with a power supply output terminal of a TYH and a TW, the thermometer measurement and control end, the fixed temperature switch Kt 1-Kt 4 and the thermistor Rt are adhered to C3, the Rt, the fixed temperature switch Kt 1-Kt 4, the potentiometer W1-W5, the timing switch K1 and the wiring terminal of the shift switch K2 are all connected with an internal circuit of TYTVDSH through bolts, a voltmeter, the thermometer, the timing switch, the shift switch, the potentiometer, the indicator light and the wiring terminal are all arranged on a panel C2C, and cast iron, stainless steel tubes and steel balls are replaced by cast aluminum, copper tubes, short copper tubes and iron rings correspondingly; cast iron or replaced by sealed aluminum nitride or graphite powder.

Example 4. method of making a D-type hot tap water vapor device:

1. selecting a stainless steel pipe 6-12 meters long and 6 minutes long, processing external threads 5cm long at two ends, and respectively installing a tee d1g with internal threads and a tee d1h at two ends, wherein the tee d1 8926 is recorded as d1 a;

2. manufacturing a 6.1 to 12.1 meter long, 1.1 cm diameter and 6 to 12 kilowatt connectable dry-burning electric heating tube d2a 1;

3. manufacturing a gasket d2a2 with the outer diameter equal to the inner diameter of a 6-minute pipe, the inner diameter equal to 1.1 cm and the thickness of 2 mm and 6 water passing bead holes;

4.d 2a2 perpendicular to d2a1 is welded on the d2a1 every 15 cm, and two capping gaskets d2a3 are respectively arranged at two ends of the d2a 1; d2a1, d2a2, d2a3 are d2 a;

5. inserting D2a into D1a, welding two ends of the D2a in alignment and bending the D1 8932 into a spiral pipe, and welding two parallel hanging plates with holes on the same plane of the upper part and the lower part of the spiral pipe to obtain a hot water vapor element D1 a;

6. manufacturing a stainless steel ball D1b, combining a water passing ball baffle plate D1c1, D1c2, an internally threaded pipe D1D1, a D1D2 and an internally installed 4 cm short and loose-proof straight pipe D1e1, D1e2, D1b, D1c1, D1c2, D1D1, D1D2, D1e1 and D1e2 into a hot water steam element D1 b; d1a and D1b are combined into a hot water element D1;

7. making a shell D, wherein a middle shell D2 of the shell D is provided with a pipe inlet hole, a pipe inlet hole and a pipe outlet hole below, a front shell of the shell D is a panel D2, the D2 is provided with an instrument, a potentiometer, a bolt, a switch and an indicator lamp mounting hole, a rear shell D2 of the shell D is provided with a mounting hole and a hook hole, a hot water steam element D and a hook D2 are simultaneously arranged inside and outside the rear shell D2, a glass fiber heat insulation layer is added on the D1, a proper amount of balls D1 are arranged in the D1, three-way side pipes at two ends of the D1 are respectively provided with a baffle plate D1c and a baffle plate D1c, the baffle plate D1c is connected with a water inlet pipe D3 and a switch D3 through internal thread pipes D1D and straight pipes D1e, the straight pipes are connected with a T-way D4, the hot water pipe D4 and the switch D4, a steam pipe D5 is connected with the D4, a safety valve D5 and a switch D5, a cooling plate D3 is arranged on a terminal, a TYHD 3 is arranged on a circuit box, the TYTWDSH input end is connected with a power supply through a D2a wire passing hole, a thermometer measuring and controlling end, a fixed temperature switch Kt 1-Kt 4 and a thermistor Rt are adhered to D1a, the Rt, Kt 1-Kt 4, potentiometers W1-W5, a timing switch K1 and a gear shift switch K2 terminal are connected with an internal circuit of the TYTWDSH through bolts, and a voltmeter, a thermometer, a timing switch, a gear shift switch, a potentiometer, an indicator light and a terminal are all installed on a panel D2 c.

D2a2 can be omitted, when rolling, D1a is filled with sand grains, two ends of D1a are sealed by a pipe head which is about 5cm long and has an electric heating pipe hole and an internal thread, D1a, D2a and the sand grains are rolled into a spiral pipe D1a, the pipe head is taken down and is provided with a tee joint, the tee joint straight pipe is welded with D2a1 and D2a3, the sand grains are poured out, and two parallel perforated hanging plates are welded on the same plane of the upper part and the lower part of the spiral pipe D1 a.

Embodiment 5. a method for manufacturing an E-type temperature-adjustable timing tap water steam device:

1. manufacturing a double-layer magnet-absorbable stainless steel solenoid e1a with a circular cross section and a spiral tube shape, wherein the bottom layer is communicated with two ends, the two ends of the double-layer magnet-absorbable stainless steel solenoid e are vertically led out upwards, the double-layer magnet-absorbable stainless steel solenoid e is provided with external threads, the interval between the two solenoids is 1-3 cm, the straight tube is two 6-12 m 4-inch steel tubes, the two solenoids with different diameters are respectively wound, then the bottom of the double-layer magnet-absorbable stainless steel solenoid e is welded, the two ends of the double-layer magnet-absorbable stainless steel solenoid are vertically led out upwards, the length of the led; e1a or winding a quarter steel tube and two round tube dies with different diameters twice;

2. manufacturing a wire-coated copper wire induction coil e2a, wherein the thickness of e2a is 0.6-2.5 cm, the diameter is half of the sum of the diameters of an inner solenoid and an outer solenoid of e1a, the height is equal to the height of e1a, the number of turns is determined by the power frequency and the current, and the length of a lead wire is about 15 cm;

3. e2a works at power frequency, the selective welding transformer e2b is used as a power supply, the primary coil of e2b is connected in parallel with a non-polar capacitor C3 consisting of a polar capacitor C3a +, a C3b +, a diode D3a, a diode D3b, a resistor R3a and a resistor R3 b;

4. the manufacturing method of the high-temperature glass insulation box e3 and e3 is that the upper and lower bottom ceramic or aluminum belt hollow inner bearing frame and the mounting hole glass positioning clamping groove e3a1a and e3a2a can be manufactured by respectively firing ceramics by mould pressing or casting, the upper and lower bottom belt hollow inner bearing frame and the mounting hole stainless steel glass positioning clamping groove e3a1b and e3a2b can be manufactured by cutting a stainless steel square tube and a flat-bottom U-shaped groove into required shapes and then spot welding, eight U-shaped flat-bottom groove wedges are spot-welded on eight corners of the upper and lower bottom stainless steel glass positioning clamping grooves e3a1b and e3a2b of the high-temperature glass insulation box, and four square tube supports with mutually vertical glass positioning clamping grooves are tightly inserted into the upper and lower four pairs of U-shaped groove wedges; the upper and lower aluminum strip hollow inner bearing frame glass positioning clamping grooves e3a1c, e3a2c can be made by cutting off redundant parts by drawing aluminum profiles e3a1c1, then performing argon arc aluminum welding and punching; four vertical columns e3b1a-e3b4a with mutually vertical glass positioning clamping grooves and positioning holes can be directly cut by drawing aluminum profiles e3b1a 1; the four upright posts e3b1b-e3b4b with the glass positioning clamping grooves and the positioning holes which are mutually vertical can be made by cutting and spot welding a stainless steel square tube and a U-shaped flat bottom groove; the upper and lower perforated porcelain plates e3c1a, e3c2a can be pressed and fired or replaced by high-temperature glass; the stainless steel bottom plate e3d with holes can be made by punching; the base e3c with the mounting hole and the hollow inner bearing frame can be made of stainless steel square tubes and flat tubes by cutting, punching and argon arc welding; a piece of large high-temperature glass is cut into an integer according to the size which is almost the same as that of the heat insulation box, and the sizes of other parts are determined by the size; buying the bolt or screw matched with the jack and assembling all the parts into the insulation can e 3;

5. manufacturing absorbable magnet steel balls e1b which can be poured into and poured out of the spiral pipe, baffles e1c1 and e1c2 which can not overflow the steel balls, internal thread pipes e1d1 and e1d2 and built-in loose straight pipes e1e1 and e1e2 which are 4 cm short and loose; e1b, E1c1, E1c2, E1d1, E1d2, E1E1, E1E2, E2a, E2b and E3 are hot water elements E1 b; e1a and E1b are E1;

6. making a shell E, wherein a middle shell E2 of the shell E is provided with a pipe inlet hole, a pipe inlet hole and a pipe outlet hole below, the front shell of the shell E is a panel E2, the E2 is provided with an instrument, a potentiometer, a bolt, a switch and an indicator lamp mounting hole, a rear shell E2 of the shell E is provided with a mounting hole and a hook hole, a hot water steam element E1 and a hook E2 are simultaneously arranged inside and outside the rear shell E2, the E1 is placed in a high-temperature glass fiber incubator, a proper amount of ball E1 is arranged in the E1, two ends of the E1 are respectively provided with a baffle plate E1c and a baffle plate E1c, the baffle plates E1c are respectively arranged at the two ends of the E1d and the E1d, and one ends of straight pipes E1E and E1E are connected with a water inlet pipe E3 and a switch E3, the other ends of the straight pipes E1E and E1E 3 are connected with a tee E4, a hot water pipe E4 and a switch E4, a steam pipe 5 is respectively connected with an E3, a steam pipe 5, a cooling plate E3, a constant temperature terminal is arranged on the, the TYTWDSH input end is connected with a power supply through a D2a wire passing hole, a thermometer measuring and controlling end, a fixed temperature switch Kt 1-Kt 4 and a thermistor Rt are adhered to E3, the Rt, Kt 1-Kt 4, W1-W5, a timing switch K1 and a gear shift switch K2 terminal are connected with an internal circuit of the TYTWDSH through a bolt, and a voltmeter, a thermometer, a timing switch, a gear shift switch, a potentiometer, an indicator light and a terminal are all arranged on a panel E2 c; e3 or glass fiber, e2a or a spiral tubular electrothermal tube e2 d; e3 made of stainless steel and high-temperature glass or e2a is removed, an iron shell electric heating plate e2c is placed between e3c and e3d, e1a is placed on e2c, e2c is connected to the secondary side of a power frequency transformer e2b through a shift switch K3 and TYTVDH, and a temperature adjusting circuit TWDL in a pressure-adjusting constant-temperature timing circuit box TYTVDH is connected or not connected;

7. the output end of a voltage-regulating temperature-controlling box TYTHDSH arranged on E3c is connected with the input end of a transformer E2b, and the output end of E2b is connected with the input end of an induction coil E2 a; the stainless steel pipe is vertically bent and is replaced by a stainless steel elbow, the stainless steel pipe and the elbow or a galvanized pipe and the elbow.

Examples 1-5 all have the following circuits:

the voltage-reducing bidirectional thyristor voltage-regulating circuit YCJYSXKKGTYDL1 is composed of bidirectional thyristors BCR1-BCR6, current-limiting resistors R1a-R6a, load resistors R1b-R6b, a potentiometer W1, capacitors C1 1, a photocoupler PC817a1, a PC817b1, a timing switch K1 1, a shift switch K2 1 and fixed temperature switches Kt1 1-Kt 4 1, common ends of BCR1 anodes, R6 1 and C1 1 are connected with a power supply live wire through a fuse BX1, common ends of BCR1 anodes and R11 at one ends are connected with a cathode of BCR1, common ends of BCR1 and R2 1 are connected with the BCR1, common ends of cathodes of the BCR1 and R3 BCR1 at one ends are connected with a BCR1 cathode of the BCR1, cathodes of the BCR1 and a common ends of the BCR1 and a cathode of the BCR 365-C1 1, and a cathode of a common end of the BCR1 and a cathode of the BCR1 are connected with a common end 365-C1 1, and a common end of a cathode of a BCR1, and a cathode of a BCR1, a cathode 365-C1 1, and a cathode of a common end of, the common end of one end of W1 and the sliding end is connected with the other end of R6a, the control pole of BCR6 is connected with the input end of a timing switch K1a, the output end of K1a is connected with the fixed end of a shift switch K2a, the sliding end of the shift switch K2a is respectively connected with the input ends of fixed temperature switches Kt1a-Kt4a, the collector electrode of the phototriode in PC817a1 and the common end of the emitter electrode of the phototriode in PC817b1, the common end of the output end of Kt1a-Kt4a, the common end of the collector electrode of the phototriode in PC81a1 and the collector electrode of the phototriode in PC817b1 are connected with; the emitting electrodes of the two phototriodes can be connected in series with a diode with the same polarity direction.

The voltage-reducing controlled silicon voltage-regulating circuit YCJYSXKKGTYDL2 is composed of bidirectional controlled silicon BCR7-BCR17, current-limiting resistors R7a-R17a, load resistors R7b-R17b, a potentiometer W2, a photoelectric coupler PC817a2, PC817b2, a timing switch K1 2, a shift switch K2 2 and a fixed temperature switch Kt1 2-Kt 4 2, the anode of the BCR2, the cathode of the BCR2 and the common end at one end of the C2 2 are connected with a power supply live wire through a fuse, the anode of the BCR2, the cathode of the BCR2 and one end of the R2 are connected with the common end of the cathode of the BCR2 and the anode of the BCR2, the anode of the BCR2, the cathode of the BCR2, the cathode of the BCR 361314, the BCR2, the cathode of the BCR2, the anode of the BCR2, the common end 15172, the cathode of the BCR2, the anode of the common end of the BCR2, the anode of the BCR 36, The common ends of the other ends of C2a and C2b are connected to the power ground, R7a, R9a, R11a, R13a and R15a are respectively connected to BCR7, BCR9, BCR11, BCR13 and BCR15 control electrodes at one end, the common end of the other end is connected to the cathode of BCR17 through a resistor R17b, resistors R8a, R10a, R12a, R14a and R16a are respectively connected to BCR8, BCR10, BCR12, BCR14 and BCR16 control electrode at one end, the common end of the other end is connected to the anode of BCR17 and the common end of the resistor R17a at one end, the other end of R17a is connected to W a and the common end of the sliding end, the control electrode of BCR a is connected to the input end of the timing switch K1a, the output end of the optical shift switch K1a is connected to the optical shift switch K2K 72, the fixed end of the sliding switch K72 is connected to the emitter a a of the triode a, and the emitter a b of the fixed switch 72 a-emitter a b of the emitter a, the common end of the output ends of Kt1b-Kt4b, the emitter of the phototriode in PC817a2 and the collector of the phototriode in PC817b2 are connected with the other end of W2; two phototriodes can be connected in series with a diode in the same polarity direction;

the voltage-reducing bidirectional thyristor voltage-regulating circuit YCJYSXKKGTYDL sequentially comprises bidirectional thyristors BCR-BCR, BCR6, current-limiting resistors R1-R6, R6a, load resistors R1-R6, potentiometers W, W1, capacitors C1, photoelectric couplers PC817a, PC817b, a timing switch K1, a gear-shifting switch K2 and fixed temperature switches Kt 1-Kt 4, wherein the common end of the BCR anode, the BCR6 anode, R6a and C1 one end is connected with a live wire through a fuse BX, the BCR anode, one end of R6 and one end of C1 are connected with the BCR6 cathode in common, the other end of R6a is connected with the common end of W1 one end and the sliding end, the other end of W1 is connected with the BCR6 control electrode, the common end of the BCR anode and one end of R1 is connected with the BCR cathode, the common end of the BCR anode and one end of R2 is connected with the BCR anode and the BCR cathode of BCR3, the BCR cathode, the common end of the BCR5 and the common end of R5 and the cathode of the BCR5, The other ends of C1a, C1b and C1C are connected with a power ground wire, one ends of R1a-R5a are respectively connected with a control electrode of BCR1-BCR5, a common end of the other ends of R1a-R5 is connected with a cathode of BCR6 through R6b, one end of W1 and a common end of a sliding end are connected with the other end of R6a, a control electrode of BCR6 is connected with an input end of a timing switch K1a, an output end of K1a is connected with a fixed end of a shift switch K2a, a sliding end of a shift switch K2a is respectively connected with an input end of a fixed temperature switch Kt1a-Kt4a and a common end of a collector of a photosensitive triode in PC817a1 and an emitter of a photosensitive triode in PC817b1, a common end of an output end of Kt1a-Kt4a and a common end of a photosensitive triode in PC81a 817b1 are; the emitting electrodes of the two phototriodes can be connected with diodes with the same polarity direction in series; r1a-R5a are connected in series into an anti-parallel diode or a bidirectional diode; r1b-R5b or replaced by a capacitor;

the voltage-reducing controlled silicon voltage-regulating circuit YCJYSXKKGTYDL4 is composed of bidirectional controlled silicon BCR7-BCR17, BCR17a, current-limiting resistors R7a-R17a, R17a a, load resistors R7a-R17a, potentiometers W a, W2a, photocoupler PC817a a, PC817b a, timing switch K1a, shift switch K2a, fixed temperature switches Kt1a-Kt4a, an anode of the BCR a, a cathode of the BCR a, a common end of the BCR a, a cathode of the BCR a, a common end of the BCR a, a cathode of the BCR a, an anode of the BCR a, a cathode of the BCR a, a common end of the BCR a, a cathode of the common end of the BCR a, an anode of the BCR a, a cathode of the BCR a, an anode of the common end of the BCR a, a cathode of the anode of the BCR a, a a, one end of each of R13a and R15a is connected to BCR7, BCR9, BCR11, BCR13, and BCR13 control electrodes, the common end of the other end is connected to BCR13 cathode through resistor R17 13, one end of each of resistors R8, R10 13, R12 13, R14 13, and R16 13 is connected to BCR13, and BCR13 control electrodes, the common end of the other end is connected to BCR17 13 anode, the common end of resistor R17a 13, the common end of BCR 72, R17 13 anode, and one end of C2 13 are connected to BCR17 13 cathode, the other end of R17a 13 is connected to W2 13 terminal and the common end of sliding terminal, the other end of W2 13 is connected to the control electrode of BCR17a 13, the common end of R13, the other end of C2 13 is connected to the common end of the sliding switch 13, the fixed switch 13, the collector 13 is connected to the switch 13, the fixed end of the switch 13, the fixed switch 13, the collector 13, the fixed end of the switch 13 is connected to the switch 13, the fixed end of the switch 13, the fixed switch 13, the collector 13 is connected to the switch 13, the fixed, The common end of the emitter of the phototriode in the PC817b2, the common end of the output end of Kt1b-Kt4b, the common end of the emitter of the phototriode in the PC817a2 and the common end of the collector of the phototriode in the PC817b2 are connected with the other end of the W2; two phototriodes can be connected in series with a diode in the same polarity direction; r7a-R16a are connected in series into an anti-parallel diode or a bidirectional diode, and R78b, R910b, R1314b and R1516b are replaced by capacitors;

the voltage-reducing bidirectional thyristor voltage-regulating circuit YCJYSXKKGTYDL is packaged in a module cooling plate MKLQB1 in TYTWDSH, and is connected with the outside of MKLQB1 through a plug pin and a binding post on a TYTWDSH panel to form a temperature-regulating circuit TWDL, wherein the TWDL comprises a transformer B1, a1A rectifier bridge, a polarity electric passenger C1+, a C2+, a diode D1, a D2, a voltage-stabilizing tube ZW, a voltage-stabilizing module 7805, a 7812, a current-limiting resistor R1C, an R2C, an R3C, an R4C, a field-effect tube NMOS C, a triode BG C, a light-emitting diode D C, a photocoupler PC 817C, a P817C, a potentiometer W C-W C and a thermistor Rt, a primary side of the B C is connected with a 220 power supply, a secondary side 12V is connected with the input end of the 1A rectifier bridge module, the positive pole 7812 input end of the rectifier bridge module, the positive pole of the C C + C, the common cathode 78R 72, the anode of the sliding anode C, the anode of the anode C, the anode of the sliding meter of the anode C, the sliding meter of the, the other end of the W5 is connected with the common end of the positive electrode of the digital display thermometer and one end of the R4C, the other end of the W3 is connected with the common end of the control electrode of the NMOS1, one end of the Rt and the cathode of the voltage regulator tube ZW, the common end of the source of the NMOS1 and the anode of the voltage regulator tube ZW is connected with one end of a potentiometer W4 through R2C, the common end of the other end of the W57328 and the other end of the Rt is grounded, the other end of the R3C is connected with the anode of a light emitting diode D3, the cathode of the D3 is connected with the anode of the light emitting diode in the PC817a, the cathode of the light emitting diode in the PC 63 a is connected with the anode of the light emitting diode in the PC817b, the cathode of the light emitting diode in the PC817b is connected with the emitter of the BG2, the base of the BG2 is connected with the emitter of the sliding 2, the base of the BG2 is connected with the W2, and the collector 3605 and 7805 are connected with the collector of the direct current collector 2.

The voltage-regulating and temperature-regulating timing circuit TYTHDDL is arranged on a circuit board in the voltage-regulating and temperature-regulating constant-temperature box TYTHDSH and is connected with an external circuit through a bolt and a binding post on a panel. TYTGDSH is formed by the aluminum alloy drawing, outside is level and smooth from top to bottom, there is radiator vane both sides, inside cross-section is the rectangle, it is level and smooth from top to bottom, there are multistage confession module cooling plate MKLQB slip positive guide rail and circuit board slip negative guide rail both sides, MKLQB cross-section both sides have can be in TYTGDSH inside both sides positive guide rail on gliding negative guide rail and ventilation passageway, inside central authorities are a rectangular channel, both sides are all drawn close a distance towards the central line from top to bottom, communicate with each other with the central channel, the same rectangular channel of shape, silicon controlled rectifier or IGBT regulator circuit just encapsulates in these three passageways, the timing circuit of adjusting the temperature is welded on inserting the circuit board on TYTGDSH inside negative guide rail, on TYTGDSH's front and back panel, on both sides cooling vane, the bottom all has the mounting hole to install instrument, the fan, the potentiometre, the bolt, the terminal, shift switch, pilot lamp etc. The control circuit accessed by two connecting points H1 and H2 in the voltage-reducing thyristor voltage-regulating circuit YCJYSXKKGTYDL in sequence is the same as the control circuit accessed by two connecting points H1 and H2 in the IGBT alternating current voltage-regulating circuit.

Two connecting points of H3 and H4 in a voltage-reducing silicon controlled voltage regulating circuit YCJYSXKKGTYDL 1-YCJYSXKKGTYDL 4 correspond to two connecting points of H3 and H4 in TWDL.

Claims

1. A method for manufacturing a temperature-adjustable timing tap hot water steam device is characterized in that: the method for manufacturing the A-type temperature-adjustable timing tap water steam device comprises the following steps:

(1) manufacturing a plane spiral stainless steel tap water pipe a1a, a dryly-heatable electric heating tube a2a and a2b, wherein two ends of the bottom of the plane spiral stainless steel tap water pipe are circular, the middle of the plane spiral stainless steel tap water pipe is rectangular, the semicircular central plane of the bottom of the outer end of the plane spiral stainless steel tap water pipe is led out, and the inner end of the plane spiral stainless steel tap water pipe is led; a2a is tightly attached to the inside of a1a, a2b is tightly sleeved on the outside of a1a, the distance between the wiring ends is 5-10 cm, and the heights of the vertical upward bent parts of the two ends of a2a and a2b are about 5 cm;

(2) making two square-round bottoms, two ends of which are vertically led out upwards and can be connected with electric heating tubes a2a and a2b for dry burning; a2a is tightly attached to the inside of a1a, a2b is tightly sleeved on the outside of a1a, the distance between the wiring ends is 5-10 cm, and the heights of the vertical upward bending parts of the two ends of a2a and a2b are about 5 cm;

(3) manufacturing stainless steel balls a1b which can be poured into and poured out of the spiral pipe a1a, stainless steel baffles a1c1 and a1c2 which have small holes with the same diameter at two ends and can not pass through the balls after being washed with water, and internally-threaded pipes a1d1 and a1d2 which have baffles at two ends and are slightly shorter than 4 cm and internally-arranged non-thick and non-thin straight pipes a1e1 and a1e 2; a1b, A1c1, A1c2, A1d1, A1d2, A1e1 and A1e2 are combined into a hot water steam element A1 b;

(4) the mold for manufacturing the heat-conducting shell a3 of the hot water vapor element A1a is as follows: the thickness of the a3 shell is about 5 mm, besides the a2a, a2b and a1a parts can be wrapped, the bottoms of the two sides of the long side are also provided with two wings with mounting holes, the thickness is about 5 mm, and the two wings with mounting holes can be replaced by iron sheets with welded holes;

(5) a2a, a2b and A1a are welded in the same plane, four terminals of an electric heating tube are tied by soft ropes, the four terminals are hung in a die and are leveled, molten iron is injected, and the hot water steam element A1a is obtained after cooling and demoulding, wherein A1a and A1b are combined into a hot water steam element A1;

(6) making a shell A, wherein a middle shell A2 of the shell A is provided with a pipe inlet hole, a pipe inlet hole and a pipe outlet hole below, a front shell of the shell A is a panel A2, the A2 is provided with an instrument, a potentiometer, a bolt, a switch and an indicator lamp mounting hole, a rear shell A2 of the shell A is provided with a mounting hole and a hook hole, a hot water steam element A1 and a hook A2 are simultaneously arranged inside and outside the rear shell A2, a glass fiber heat preservation layer is added on the A1, a proper amount of balls A1 are arranged in the A1, two ends of the A1 are respectively provided with a baffle plate A1c and A1c, the baffle plate A3c is connected with a tap water pipe A3 and a switch A3 through inner thread pipes A1d and straight pipes A1e and A1e, the lower end of the tap water pipe A4, the hot water pipe A4 and the switch A4, the steam pipe A5 is connected with the A4, the safety valve A5 and the switch A5, a cooling plate A3 is arranged on the A3, a constant temperature circuit box is arranged on the A3 during pressure regulation, a TYH constant temperature circuit box is arranged on the TWH, the input end of TYTVDSH is connected with a power supply through an A2a wire passing hole, the measurement and control end of a thermometer, a fixed temperature switch Kt 1-Kt 4 and a thermistor Rt are adhered to a3, the Rt, Kt 1-Kt 4, potentiometers W1-W5, a timing switch K1 and a wiring terminal of a gear shift switch K2 are all connected with an internal circuit of TYTVDSH through bolts, a voltmeter, a thermometer, a timing switch, a gear shift switch, a potentiometer, an indicator light and a wiring terminal are all arranged on a panel A2c, and cast iron, a stainless steel pipe and a steel ball are replaced by cast aluminum, a copper pipe, a short copper pipe and an iron ring correspondingly; cast iron or replaced by sealed aluminum nitride or graphite powder.

2. A method for manufacturing a temperature-adjustable timing tap hot water steam device is characterized in that: the manufacturing method of the B-type temperature-adjustable timing tap water steam device comprises the following steps:

(1) manufacturing a solenoid-shaped stainless steel tap water pipe b1a with an external thread interface, wherein two ends of the section of the solenoid-shaped stainless steel tap water pipe b1 are circular, the middle of the solenoid-shaped stainless steel tap water pipe b1 is narrow and rectangular, two ends of the solenoid-shaped stainless steel tap water pipe b are vertically bent upwards and downwards, the length of the straight pipe b1a is 6-12 meters of a 4-minute stainless steel pipe, b1a is vertical or horizontal, two ends of the solenoid-shaped stainless steel tap water pipe b are vertically led out upwards and downwards, two parts without threads are respectively 5 centimeters, parts with;

(2) manufacturing stainless steel balls B1B, combining water passing ball baffles B1c1, B1c2, internally threaded pipes B1d1, B1d2 and internally-arranged 4 cm short and loose-proof straight pipes B1e1 and B1e2, B1B, B1c1, B1c2, B1d1, B1d2, B1e1 and B1e2 into a hot water steam element B1B;

(3) manufacturing U-shaped electric heating tubes b2a1 and b2a2 with two ends bent vertically upwards and capable of being connected in a dry-burning mode, wherein the length of each U-shaped electric heating tube is equal to the height of the spiral tube plus 5-10 cm;

(4) the mould for manufacturing the B1a heat-conducting shell B3 is about 5 mm thick, two wings with mounting holes are arranged at the bottoms of two sides of the long side except for surrounding B1a, B2a1 and B2a2, and the thickness is about 5 mm and is parallel to the center of the spiral pipe;

(5) welding U-shaped electric heating tubes B2a1 and B2a2 on the inner wall of B1a in parallel, tying four terminals of the electric heating tubes by soft ropes, hanging the electric heating tubes into a die, leveling, injecting molten iron, and cooling to obtain a hot water steam element B1 a; b1a and B1B are combined into a hot water steam element B1;

(6) making shell B, the middle shell B2 of B has inlet tube hole, inlet wire hole, lower outlet tube hole, the front shell of B is panel B2, the B2 has instrument, potentiometer, bolt, switch, indicator lamp mounting hole, the back shell B2 of B has mounting hole, hook hole, the inside and outside of the back shell B2 is equipped with hot water steam element B1 and hook B2, and adds glass fiber heat preservation layer to B1, B1 is equipped with proper amount of ball B1, the two ends of B1 are equipped with baffle plates B1c, and connected with inlet water tube B3, switch B3 through internal thread tube B1d, B1d and straight tube B1e, the lower end is connected with three-way B4, hot water tube B4, switch B4, steam tube B5 is connected with B4, safety valve B5, switch B5, cooling plate B3 is installed on B3, the constant temperature circuit box TYH is installed on B3 when adjusting pressure, the TYH is connected with the output of DSH, TYH 2 and TWb 2 of electric heating tube and TWb 2, the TYTWDSH input end is connected with a power supply through a B2a wire passing hole, a thermometer measuring and controlling end, a fixed temperature switch Kt 1-Kt 4 and a thermistor Rt are adhered to B3, the Rt, the fixed temperature switch Kt 1-Kt 4, a potentiometer W1-W5, a timing switch K1 and a gear shift switch K2 are connected with an internal circuit of the TYTWDSH through bolts, a voltmeter, a thermometer, a timing switch, a gear shift switch, a potentiometer, an indicator light and a binding post are all arranged on a panel B2c, and cast iron, a stainless steel pipe and a steel ball are replaced by cast aluminum, a copper pipe, a short copper pipe and an iron ring correspondingly; cast iron or replaced by sealed aluminum nitride or graphite powder.

3. A method for manufacturing a temperature-adjustable timing tap hot water steam device is characterized in that: the manufacturing method of the C-shaped temperature-adjustable timing tap water steam device comprises the following steps:

(1) manufacturing stainless steel screwed pipe-shaped tap water pipes c1a and c1a with round sections and two ends which are vertically bent up and down respectively and provided with external threaded interfaces, or vertically or horizontally placing the stainless steel screwed pipe-shaped tap water pipes c1a and c1 a; the bent parts of the upper and lower unthreaded parts at the two ends are about 5cm long respectively, and the parts with the upper and lower external threads are about 5cm long respectively;

(2) making U-shaped electric heating tubes c2a1-c2a4 with two ends bent upwards vertically and capable of being connected for dry burning;

(3) manufacturing stainless steel balls c1b which can be poured into and poured out of a stainless steel pipe, end baffles c1c1 and c1c2 which can not pass through the stainless steel pipe after being washed with water, internal threaded pipes c1d1 and c1d2 and built-in slightly short and loose straight pipes c1e1 and c1e 2; c1b, C1C1, C1C2, C1d1, C1d2, C1e1 and C1e2 are combined into a hot water steam element C1 b;

(4) manufacturing a mold for pouring a heat-conducting shell C3 of a hot water steam element C1a, wherein the thickness of C3 is about 5 mm, two wings with mounting holes are arranged at the bottoms of two sides except for surrounding C1a and C2a1-C2a4, and the two wings are parallel to a central line;

(5) uniformly and vertically sticking the electrothermal tube c2a1-c2a4 on the inner wall of the spiral tube c2a, and welding; tying the four electric heating tube terminals by using soft ropes, hanging the electric heating tube terminals into a mold, leveling the electric heating tube terminals, injecting molten iron, and cooling to obtain a hot water vapor element C1 a; c1a and C1b are combined into hot water steam elements C1 and C1a or consist of C1a with C2a1-C2a4 welded on the inner wall, a preheating water cylinder C1f with sealing heads and 4-branch threaded pipes which are arranged in the preheating water cylinder and tightly attached to two ends, an iron sheet with holes welded on the outer part and heat-insulating glass filaments;

(6) making a shell C, wherein a middle shell C2 of the shell C is provided with a pipe inlet hole, a pipe inlet hole and a pipe outlet hole below, a front shell of the shell C is a panel C2, the C2 is provided with an instrument, a potentiometer, a bolt, a switch and an indicator lamp mounting hole, a rear shell C2 of the shell C is provided with a mounting hole and a hook hole, a hot water steam element C1 and a hook C2 are simultaneously arranged inside and outside the rear shell C2, a glass fiber heat preservation layer is added on the C1, a proper amount of balls C1 are arranged in the C1, two ends of the C1 are respectively provided with a baffle plate C1C and a baffle plate C1C, and are respectively connected with a tap water pipe C3 and a switch C3 through inner thread pipes C1d and straight pipes C1e and C1e, the lower end of the straight pipes is connected with a tee joint C4, a hot water pipe C4 and a switch C4, the steam pipe C5 is respectively connected with the C4, a safety valve C5 and a switch C5, a cooling plate C3 is arranged on the C3, a constant temperature circuit box is arranged on the TYH 3 during pressure regulation, a TWH output terminal of the T, the TYTWDSH input end is connected with a power supply through a C2a wire passing hole, a thermometer measuring and controlling end, a fixed temperature switch Kt 1-Kt 4 and a thermistor Rt are adhered to C3, the Rt, the fixed temperature switch Kt 1-Kt 4, a potentiometer W1-W5, a timing switch K1 and a gear shift switch K2 are connected with an internal circuit of the TYTWDSH through bolts, a voltmeter, a thermometer, a timing switch, a gear shift switch, a potentiometer, an indicator light and a binding post are all arranged on a panel C2C, and cast iron, a stainless steel pipe and a steel ball are replaced by cast aluminum, a copper pipe, a short and short copper pipe and an iron ring correspondingly; cast iron or replaced by sealed aluminum nitride or graphite powder.

4. A method for manufacturing a temperature-adjustable timing tap hot water steam device is characterized in that: the manufacturing method of the D-type tap water steam device comprises the following steps:

(1) selecting a stainless steel pipe 6-12 meters long and 6 minutes long, processing external threads 5cm long at two ends, and respectively installing a tee d1g with internal threads and a tee d1h at two ends, wherein the tee d1 8926 is recorded as d1 a;

(2) manufacturing a 6.1 to 12.1 meter long, 1.1 cm diameter and 6 to 12 kilowatt connectable dry-burning electric heating tube d2a 1;

(3) manufacturing a gasket d2a2 with the outer diameter equal to the inner diameter of a 6-minute pipe, the inner diameter equal to 1.1 cm and the thickness of 2 mm and 6 water passing bead holes;

(4) d2a2 perpendicular to d2a1 is welded on the d2a1 every 15 cm, and two capping gaskets d2a3 are respectively arranged at two ends of the d2a 1; d2a1, d2a2, d2a3 are d2 a;

(5) inserting D2a into D1a, welding two ends of the D2a in alignment and bending the D1 8932 into a spiral pipe, and welding two parallel hanging plates with holes on the same plane of the upper part and the lower part of the spiral pipe to obtain a hot water vapor element D1 a;

(6) manufacturing a stainless steel ball D1b, combining a water passing ball baffle plate D1c1, D1c2, an internally threaded pipe D1D1, a D1D2 and an internally installed 4 cm short and loose-proof straight pipe D1e1, D1e2, D1b, D1c1, D1c2, D1D1, D1D2, D1e1 and D1e2 into a hot water steam element D1 b; d1a and D1b are combined into a hot water element D1;

(7) making a shell D, wherein a middle shell D2 of the shell D is provided with a pipe inlet hole, a pipe inlet hole and a pipe outlet hole below, a front shell of the shell D is a panel D2, the D2 is provided with an instrument, a potentiometer, a bolt, a switch and an indicator lamp mounting hole, a rear shell D2 of the shell D is provided with a mounting hole and a hook hole, a hot water steam element D and a hook D2 are simultaneously arranged inside and outside the rear shell D2, a glass fiber heat insulation layer is added on the D1, a proper amount of balls D1 are arranged in the D1, three-way side pipes at two ends of the D1 are respectively provided with a baffle plate D1c and a baffle plate D1c, the baffle plate D1c is connected with a water inlet pipe D3 and a switch D3 through internal thread pipes D1D and straight pipes D1e, the straight pipes are connected with a T-way D4, the hot water pipe D4 and the switch D4, a steam pipe D5 is connected with the D4, a safety valve D5 and a switch D5, a cooling plate D3 is arranged on a terminal, a TYHD 3 is arranged on a circuit box, the TYTWDSH input end is connected with a power supply through a D2a wire passing hole, a thermometer measuring and controlling end, a fixed temperature switch Kt 1-Kt 4 and a thermistor Rt are adhered to D1a, the Rt, Kt 1-Kt 4, potentiometers W1-W5, a timing switch K1 and a gear shift switch K2 terminal are connected with an internal circuit of the TYTWDSH through bolts, and a voltmeter, a thermometer, a timing switch, a gear shift switch, a potentiometer, an indicator light and a terminal are all arranged on a panel D2 c;

d2a2 or not, when rolling, D1a is filled with sand grains, the two ends of D1a are sealed by a pipe head which is about 5cm long and has an electric heating pipe hole and an internal thread, D1a, D2a and the sand grains are rolled into a spiral pipe D1a, the pipe head is taken down and is provided with a tee joint, the straight pipe of the tee joint is welded with D2a1 and D2a3, the sand grains are poured out, and two parallel perforated hanging plates are welded on the same plane of the upper part and the lower part of the spiral pipe D1 a.

5. A method for manufacturing a temperature-adjustable timing tap hot water steam device is characterized in that: the manufacturing method of the E-type temperature-adjustable timing tap water steam device comprises the following steps:

(1) manufacturing a double-layer magnet-absorbable stainless steel solenoid e1a with a circular cross section and a spiral tube shape, wherein the bottom layer is communicated with two ends, the two ends of the double-layer magnet-absorbable stainless steel solenoid e are vertically led out upwards, the two ends of the double-layer magnet-absorbable stainless steel solenoid e are provided with external threads, the surface of the solenoid is spaced by 1-3 cm, a straight tube is two 6-12 m and 4 min steel tubes, the two straight tubes are respectively wound into two solenoids with different diameters, then the bottoms of the two solenoids are welded, the two ends of the double-layer magnet-absorbable stainless steel solenoid are vertically led out upwards, the length of the led; e1a or winding a 4-minute steel pipe and two circular pipe dies with different diameters twice;

(2) manufacturing a wire-covered copper wire induction coil e2a, wherein the thickness of e2a is 0.6-2.5 cm, the diameter is half of the sum of the diameters of an inner spiral tube and an outer spiral tube of e1a, the height is equal to the height of e1a, the number of turns is determined by the frequency of a power supply and the current, and the length of a lead wire is about 15 cm;

(3) e2a works at power frequency, an electric welding transformer is selected to be used as a modified power supply e2b, and a primary coil of e2b is connected in parallel with a non-polar capacitor C3 consisting of a polar capacitor C3a +, a C3b +, a diode D3a, a diode D3b, a resistor R3a and a resistor R3 b;

(4) the manufacturing method of the high-temperature glass insulation box e3, e3 is that the upper and lower bottoms of the high-temperature glass insulation box e3 are provided with hollow inner bearing frames and mounting hole glass positioning clamping grooves e3a1a and e3a2a of porcelain or aluminum belts or are manufactured by respectively firing ceramics or casting by mould pressing, the upper and lower bottoms of the high-temperature glass insulation box are provided with hollow inner bearing frames and mounting hole stainless steel glass positioning clamping grooves e3a1b and e3a2b or are manufactured by cutting stainless steel square pipes and flat-bottom U-shaped grooves into required shapes and then spot welding, eight U-shaped flat-bottom groove wedges are spot-welded on eight corners of the stainless steel glass positioning clamping grooves e3a1b and e3a2b at the upper and lower bottoms of the high-temperature glass insulation box, and four square pipe supports with mutually vertical glass positioning clamping grooves are; the upper and lower aluminum strips with hollow inner bearing frame glass positioning clamping grooves e3a1c, e3a2c or drawn aluminum profiles e3a1c1 are used for cutting redundant parts and then are manufactured by argon arc aluminum welding and punching; four vertical columns e3b1a-e3b4a with mutually vertical glass positioning clamping grooves and positioning holes or drawn aluminum profiles e3b1a1 are directly cut; the glass positioning clamp groove and the positioning hole are mutually vertical, and four upright posts e3b1b-e3b4b are arranged or are made by cutting and spot welding a stainless steel square tube and a U-shaped flat bottom groove; the upper and lower bottom porcelains e3c1a, e3c2a are either die-pressed and fired or are replaced by high-temperature glass; the stainless steel bottom plate e3d with holes is made by punching; the base e3c with the mounting hole and the hollow inner bearing frame is manufactured by cutting, punching and argon arc welding a stainless steel square pipe and a flat pipe; cutting a large piece of high-temperature glass into an integral number according to the size similar to that of the heat preservation box, drilling pipe holes and wire through holes, purchasing bolts or screws matched with jacks, assembling all parts into the heat preservation box E3, placing E2a in E1a, placing E2a and E1a in E3, and combining the parts into a hot water steam element E1 a;

(5) manufacturing absorbable magnet steel balls e1b which can be poured into and poured out of the spiral pipe, baffles e1c1 and e1c2 which can not overflow the steel balls, internal thread pipes e1d1 and e1d2 and built-in loose straight pipes e1e1 and e1e2 which are 4 cm short and loose; e1b, E1c1, E1c2, E1d1, E1d2, E1E1, E1E2, E2a and E2b are combined into a hot water steam element E1b, and E1a and E1b are combined into a hot water steam element E1;

(6) making a shell E, wherein a middle shell E2 of the shell E is provided with a pipe inlet hole, a pipe inlet hole and a pipe outlet hole below, a front shell of the shell E is a panel E2, the E2 is provided with an instrument, a potentiometer, a bolt, a switch and an indicator lamp mounting hole, a rear shell E2 of the shell E is provided with a mounting hole and a hook hole, a hot water steam element E1 and a hook E2 are simultaneously arranged inside and outside the rear shell E2, a proper amount of balls E1 are arranged in the E1 of the E1, two ends of the E1 are respectively provided with a baffle plate E1c and a baffle plate E1c, the baffle plate E1c is arranged at the two ends of the E1d and the straight pipes E1E and E1E, one ends of the straight pipes E1d and E1d are connected with a water inlet pipe E3 and a switch E3, the other ends of the straight pipes E1E and E1E 3 are connected with a tee joint E4, a hot water pipe E4 and a switch E4, a steam pipe 5 is connected with the steam pipe E5, a cooling plate E3 is arranged on the E3, a constant temperature timing circuit box TYH type constant temperature circuit box is arranged on the terminal, the TYTWDSH input end is connected with a power supply through a D2a wire passing hole, a thermometer measuring and controlling end, a fixed temperature switch Kt 1-Kt 4 and a thermistor Rt are adhered to E3, the Rt, Kt 1-Kt 4, potentiometers W1-W5, a timing switch K1 and a gear shift switch K2 terminal are connected with an internal circuit of the TYTWDSH through bolts, and a voltmeter, a thermometer, a timing switch, a gear shift switch, a potentiometer, an indicator light and a terminal are all arranged on a panel E2 c; e2a or a coil-shaped electrothermal tube e2 d; e3 made of stainless steel and high-temperature glass or e2a is removed, an iron shell electric heating plate e2c is placed between e3c and e3d, e1a is placed on e2c, and e2c is connected to the secondary side of an industrial frequency transformer e2b through a shift switch K3 and TYTDSH;

(7) the output end of a voltage-regulating temperature-controlling box TYTHDSH arranged on E3c is connected with the input end of a transformer E2b, and the output end of E2b is connected with the input end of an induction coil E2 a; the stainless steel pipe is vertically bent and is turned by a stainless steel elbow, and the stainless steel pipe and the elbow or a galvanized pipe and the elbow are used for replacing the stainless steel pipe and the elbow.

6. A method for manufacturing a temperature-adjustable timing tap hot water steam device is characterized in that: the claimed claims 1-5 are to select one voltage regulation for the sequential voltage reduction bidirectional thyristor voltage regulation circuit YCJYSXKKGTYDL1-4, YCJYSXKKGTYDL1 is composed of bidirectional thyristors BCR1-BCR6, current limiting resistors R1a-R6a, load resistors R1b-R6b, a potentiometer W1, capacitors C1a, photocouplers PC817a a, PC817b a, a timing switch K1a, a shift switch K2a, and fixed temperature switches Kt1a-Kt4a, anodes of BCR a, BCR a anodes, common terminals at one ends of R6a and C1a are connected with the power supply line of fuse BX a, anodes of BCR a and R1a, common terminals at one ends of BCR a and BCR a are connected with the cathodes of R a and BCR a, cathodes at one ends of BCR a and BCR a, common terminals of BCR a and BCR a are connected with the common terminals of BCR a and BCR a, cathodes of BCR 365R a, cathodes of common terminals are connected with the common terminals of BCR a and BCR a, cathodes of common terminals 365R a, cathode terminals of common terminals of BCR a and BCR a, and common terminals of BCR a, and common terminals are connected with the common terminals of BCR a, the common end of the other end of each is connected with a cathode of a BCR6 through R6b, the common end of one end of W1 and the common end of a sliding end is connected with the other end of R6a, a control electrode H1 of the BCR6 is connected with the input end of a timing switch K1a, the output end of K1a is connected with the fixed end of a shift switch K2a, the sliding end of the shift switch K2a is respectively connected with the input ends of fixed temperature switches Kt1a-Kt4a and the common end of a collector of a photosensitive triode in PC817a1 and an emitter of a photosensitive triode in TWDL, the common end of the output end of Kt1a-Kt4a and the common end of the emitter of the photosensitive triode in PC81a1 and the collector of the photosensitive triode in PC817b1 are connected with the common end H2 at; the emitting electrodes of the two phototriodes are connected in series with diodes with the same polarity direction;

the voltage-reducing thyristor voltage-regulating circuit YCJYSXKKGTYDL in sequence is composed of a bidirectional thyristor BCR-BCR, a current-limiting resistor R7-R17, a resistor R17, a load resistor R78-R17, a potentiometer W, a photoelectric coupler PC817a, a PC817b, a timing switch K1, a shift switch K2 and a fixed temperature switch Kt 1-Kt 4, wherein the common end of one end of the BCR anode, the BCR cathode and the C2 is connected with a power and live wire through a fuse, the common end of one end of the BCR anode, the BCR cathode and the R78 is connected with the common end of the BCR cathode and the BCR anode, the common end of one end of the BCR anode, the BCR cathode and the R910 is connected with the common end of the BCR cathode and the BCR anode, the common end of one end of the BCR anode, the BCR cathode and the R1112 is connected with the common end of the BCR cathode, the BCR anode, the BCR cathode, the common end of the BCR cathode and the BCR anode is connected with the common end of the BCR cathode, the common end of the other ends of R1516b, C2a and C2b is connected with power ground, one end of each of R7a, R9a, R11a, R13a and R15a is respectively connected with BCR7, BCR9, BCR11, BCR13 and BCR15 control electrodes, the common end of the other end is connected with BCR17 cathode through a resistor R17b, one end of each of resistors R8a, R10a, R12a, R14a and R16a is respectively connected with BCR8, BCR10 control electrodes, the common end of the other end is connected with BCR10 anode and the common end of one end of resistor R17 10, the other end of R17 10 and the common end of sliding end, the control electrode of R10 is connected with the input end of light in BCR 10K 1, the output end of K1 and the switch K72 is connected with TWT 2K 2 switch, the fixed end of the emitter 10 and the emitter of the collector electrode of the TWT 10 and the fixed triode 10b of the switch 72, the common end of the output ends of Kt1b-Kt4b, the emitter of the phototriode in PC817a2 and the collector of the phototriode in PC817b2 in TWDL are connected with the other end H2 of W2; two phototriodes are connected in series with a diode in the same polarity direction;

the voltage-reducing bidirectional thyristor voltage-regulating circuit YCJYSXKKGTYDL sequentially comprises bidirectional thyristors BCR-BCR, BCR6, current-limiting resistors R1-R6, R6a, load resistors R1-R6, potentiometers W, W1, capacitors C1, photoelectric couplers PC817a, PC817b, a timing switch K1, a gear-shifting switch K2 and fixed temperature switches Kt 1-Kt 4, wherein the common end of the BCR anode, the BCR6 anode, R6a and C1 one end is connected with a live wire through a fuse BX, the BCR anode, one end of R6 and one end of C1 are connected with the BCR6 cathode in common, the other end of R6a is connected with the common end of W1 one end and the sliding end, the other end of W1 is connected with the BCR6 control electrode, the common end of the BCR anode and one end of R1 is connected with the BCR cathode, the common end of the BCR anode and one end of R2 is connected with the BCR anode and the BCR cathode of BCR3, the BCR cathode, the common end of the BCR5 and the common end of R5 and the cathode of the BCR5, The other ends of C1a, C1b and C1C are connected with a power ground wire, one ends of R1a-R5a are respectively connected with control electrodes of BCR1-BCR5, the common end of the other ends of R1a-R5 is connected with a cathode of BCR6 through R6b, one end of W1 and the common end of the sliding end are connected with the other end of R6a, a control electrode H1 of BCR6 is connected with the input end of a timing switch K1a, the output end of K1a is connected with the fixed end of a shift switch K2a, the sliding end of the shift switch K2a is respectively connected with the input ends of fixed temperature switches Kt1a-Kt4a, the collector of the photosensitive triode in PC817a a and the common end of the emitter of the photosensitive triode in PC817b a in TWDL, and the common end of the collector H a of the photosensitive triode in PC817a 3681 a a and the photosensitive triode 36817 b a in TWDL; the emitting electrodes of the two phototriodes are connected in series with diodes with the same polarity direction; r1a-R5a or series-connected bidirectional diode; r1b-R5b or replaced by a capacitor;

the voltage-reducing controlled silicon voltage-regulating circuit YCJYSXKKGTYDL4 is composed of bidirectional controlled silicon BCR7-BCR17, BCR17a, current-limiting resistors R7a-R17a, R17a a, load resistors R78-R1516 a, potentiometers W a, W2a, photocouplers PC817a a, PC817b a, a timing switch K1a, a shift switch K2a and fixed temperature switches Kt1a-Kt4a, anodes of the BCR a, cathodes of the BCR a and the C2a are connected with a power supply live wire through fuses, anodes of the BCR a, cathodes of the BCR a and the BCR a, a common BCR a cathode at one end of the R78 a and a common end of the BCR a and the BCR a are connected with a common anode of the BCR a and the anode of the BCR a, cathodes of the BCR a and the BCR a, anodes of the common ends of the anode of the BCR a and the common anode of the BCR a and the BCR a, the common anode of the BCR a and the anode of the BCR a, the common anode of the BCR a and the anode of the common a, the common anode of the BCR a and the anode of the BCR a, the anode of the BCR a and, One end of each of R13a and R15a is connected to BCR7, BCR9, and BCR9 control electrodes, the common end of the other end is connected to BCR9 cathode through resistor R17 9, one end of each of resistors R8 9, R10 9, R12 9, R14 9, and R16 9 is connected to BCR9, and BCR9 control electrodes, the common end of the other end is connected to BCR17 9 anode, the common end of resistor R17a 9, the common end of anode of BCR 72, R17 9, and one end of C2 9 is connected to BCR17 9 cathode, the other end of R17a 9 is connected to W2 9 and the common end of the sliding end, the other end of W2 9 is connected to the control electrode of BCR17 9, the common end of R9, the R9, R72, R1314, R1112, R1516, the common end of the sliding end of the switch 9, the fixed switch 9, the collector 9 is connected to the fixed switch 9, the common end of the switch 9, the fixed end of the switch 9, the fixed switch 9, the fixed end of the switch 9, the common end of the emitter of the phototriode in the PC817b2, the common end of the output end of Kt1b-Kt4b, the common end of the emitter of the phototriode in the PC817a2 and the common end of the collector of the phototriode in the PC817b2 are connected with the other end H2 of the W2; two phototriodes are connected in series with a diode in the same polarity direction; r7a-R16a or series-connected bidirectional diodes, R78b, R910b, R1314b and R1516b or are replaced by capacitors;

the voltage-reducing bidirectional thyristor voltage-regulating circuit YCJYSXKKGTYDL1 belongs to 4 different bidirectional thyristor voltage-regulating circuits in turn, or is optionally packaged in a module cooling plate MKLQB1 in TYTWDSH, and is externally connected with a temperature-regulating circuit TWDL through a plug and a binding post on a TYTWDSH panel and MKLQB 1; TWDL consists of transformer B, 1A rectifier bridge, polarity resistor C +, diode D, voltage regulator ZW, voltage regulator modules 7805, 7812, current limiting resistors R1, R2, R3, R4, field effect transistor NMOS, triode BG, light emitting diode D, photoelectric coupler PC817, P817, potentiometer W-W, thermistor Rt, the primary side of B is connected with 220 power supply, the secondary side 12V is connected with the input end of 1A rectifier bridge module, the positive pole of rectifier bridge module is connected with the input end of 7812, C + positive pole, and D cathode common end, the output end of 7812 is connected with the common end of C + positive pole, D cathode, 7805 input end, one end of R1, NMOS drain electrode, and one end of R3, the output end of 7805 is connected with the common end of D positive pole, voltmeter positive pole, one end of W and sliding end, the other end of W is connected with the common end of digital display thermometer, one end of R4, the other end of R1 and sliding end, and the other end of W is connected with control electrode, One end of Rt and a common end of a cathode of a voltage regulator tube ZW, a common end of a source electrode of an NMOS1 and an anode of the voltage regulator tube ZW is connected with one end of a potentiometer W4 through R2C, the other end of W4 and the common end of the other end of Rt are grounded, the other end of R3C is connected with an anode of a light emitting diode D3, a cathode of D3 is connected with an anode of the light emitting diode in PC817a, a cathode of the light emitting diode in PC817a is connected with an anode of the light emitting diode in PC817b, a cathode of the light emitting diode in PC817b is connected with a BG2 emitter, a BG2 base is connected with a BG1 emitter, a BG1 base is connected with a W4 sliding end, 7812 and 7805 grounding ends, a C1+ and C2+ cathode, a rectifying bridge grounding end, a digital display voltmeter and thermometer cathode, the other end of R4;

the voltage-regulating and temperature-regulating timing circuit TYTHDDL is arranged on a circuit board in the voltage-regulating and temperature-regulating constant-temperature box TYTHDSH and is connected with an external circuit through a bolt and a binding post on a panel; TYTDSH is drawn by aluminum alloy, the outside is smooth from top to bottom, there are cooling blades on both sides, the internal cross-section is rectangular, it is smooth from top to bottom, there are multistage module cooling plate MKLQB that supplies to slide the male rail and female rail of circuit board slide on both sides, MKLQB cross-section both sides have female rail and ventilation passageway that can slide on the male rail of both sides inside TYTDSH, the inside center is a rectangular channel, both sides are the upper and lower and draw close a distance toward the central line, communicate with central channel, the identical rectangular channel of shape, the silicon controlled rectifier or IGBT regulator circuit is capsulated in these three channels, the timing circuit of regulating the temperature is welded on the circuit board inserted on the female rail inside TYTDSH, the front and back panels of TYTDSH, on both sides cooling blade, bottom have mounting holes to install instruments, fans, potentiometers, bolts, terminals, shift switches, pilot lamps, TYTDSH can use independently; the control circuit accessed by two connecting points H1 and H2 in the step-down silicon controlled voltage regulating circuit YCJYSXKKGTYDL1-4 is the same as the control circuit accessed by two connecting points H1 and H2 in the IGBT alternating current voltage regulating circuit;

two connecting points of H3 and H4 in the voltage-reducing thyristor voltage-regulating circuit YCJYSXKKGTYDL1-4 correspond to two connecting points of H3 and H4 in TWDL.