CN202168232U - Electromagnetic induction heating device for heating metal workpiece - Google Patents

Abstract

An electromagnetic induction heating device for heating a metal workpiece comprises a control cabinet, a capacitor, a transformer and a heating coil. A primary coil of the transformer is connected with the capacitor in series, and a secondary coil of the transformer is connected with the heating coil in series. A main control board, a driving transformer, a driving plate, a power supply and four groups of insulated gate bipolar transistors (IGBTs) are arranged inside the control cabinet. The capacitor and the primary coil of the transformer are connected with a full-bridge inverting circuit composed of the four groups of the IGBTs, the power supply passes through a rectifying circuit and a filter circuit sequentially to be connected with the full-bridge inverting circuit, and the control end of the main control board passes through the driving transformer and the driving plate sequentially to be connected with control electrodes of the IGBTs. A mutual inductor is further arranged on a series-connection circuit of the capacitor and the primary coil of the transformer, and the output end of the mutual inductor is connected with a feedback signal detecting end of the main control board. The heating device is simple in circuit structure, low in failure rate, has high stability and heating efficiency, can adjust frequency of alternating current according to requirements, is convenient to adjust and big in adjusting range.

Description

A kind of electromagnetic induction heater that is used for the heating of metal workpiece

Technical field

The utility model relates to a kind of electromagnetic induction heater, specifically a kind of electromagnetic induction heater that is used for the heating of metal workpiece.

Background technology

In the manufacturing of metal works, quenching is an important treatment step.Quenching can improve the hardness and the resistance to wear of metal works, thereby is widely used in various workers, mould, measurer and requires the part of surface abrasion resistance, like gear, roll, carburized parts etc.In the present quenching processing technology, adopt the flame heat workpiece usually, this mode of heating needs consume fuel, and most heat is dispersed in the environment in the heating process, has wasted mass energy, and energy utilization rate is low.Original flame heat mode need heat whole workpiece, can't do local heat treatment, and energy resource consumption is big, and whole heating causes workpiece deformation big, influences the workpiece end product quality.Electromagnetic induction heating is through in induction coil, feeding the alternating current of certain frequency, around coil, producing alternating magnetic field.The electromagnetic induction effect of alternating magnetic field makes the induced current that produces sealing in the workpiece, i.e. eddy current.The eddy current that produces directly generates heat metal, thereby has reduced thermal loss greatly, has improved capacity usage ratio.Therefore, electromagnetic induction is a great development trend of metal works heating.

The utility model content

The utility model technical problem to be solved provides a kind of electromagnetic induction heater that is used for the heating of metal workpiece, has the advantage stable, that firing rate is fast.

The utility model is to solve the problems of the technologies described above the technical scheme that is adopted to be: a kind of electromagnetic induction heater that is used for the heating of metal workpiece; Comprise control cubicle, capacitor, transformer and heater coil; Primary winding in the transformer and capacitor series; Secondary coil in the transformer is connected in series with heater coil, is provided with master control borad, driving transformer, drive plate, power supply and four groups of IGBT in the control cubicle, and the primary winding of capacitor and transformer is connected with the full bridge inverter that four groups of IGBT form; First group of IGBT is connected with the 4th group of IGBT with the primary winding serial connection back of capacitor and transformer successively; Second group of IGBT is connected with the 3rd group of IGBT successively with behind the primary winding of transformer and the capacitor series, and first group of IGBT and second group of IGBT input also connect, and the 3rd group of IGBT and the 4th group of IGBT output also connect; Power supply is connected with full bridge inverter through behind rectification circuit and the filter circuit successively, and the control end of master control borad passes through driving transformer successively and is connected with the control utmost point of IGBT with drive plate; Also be provided with instrument transformer on the series circuit of the primary winding of capacitor and transformer, the output of instrument transformer is connected with the feedback signal test side of master control borad.

In the described full bridge inverter, be equipped with the IGBT of two parallel connections among every group of IGBT.

The connection line of described filter circuit and full bridge inverter was provided with flow sensor, and the output of crossing flow sensor is connected with master control borad.

Described IGBT is provided with water cooling plant, is provided with water cavity in the water cooling plant, and water cavity is provided with water inlet and delivery port.

Described IGBT is provided with temperature sensor, and the water inlet of said water cooling plant is provided with flow sensor, and the output of flow sensor and temperature sensor is connected with the test side of master control borad.

Described heater coil is arranged in the cooling collar, and the coiling mode of cooling collar is identical with the coiling mode of heater coil, is provided with the sleeve pipe import at an end of cooling collar, and the other end is provided with the sleeve pipe outlet.

Described transformer is provided with cooling device; Cooling device comprises the water cooling tube that is enclosed within on the transformer coil lead and is arranged on the cooling water box on the iron core; The coiling mode of water cooling tube is identical with the coiling mode of transformer coil lead; End at water cooling tube is provided with the water pipe import, and the other end is provided with pipe outlet; The cooling water box is provided with import of water box and the outlet of water box.

Described cooling water box, the outlet of its water box import and water box is connected with aqueduct respectively, the aqueduct setting of spiraling in the form of a ring.

Described rectification circuit is a bridge rectifier, and described filter circuit is the RC filter circuit.

Described power supply is provided with lack detection circuit and over-voltage detection circuit, and the output of lack detection circuit and over-voltage detection circuit is connected with master control borad respectively.

The beneficial effect of the utility model is: in the present technique scheme, power supply changes alternating current into by full bridge inverter again after over commutation, filtering.In full bridge inverter, adopt the conducting and the shutoff of IGBT Control current, improved the stability and the efficiency of heating surface of load circuit, and simplified the circuit composition, reduced failure rate.After boosting through driving transformer, the control signal of master control borad, adjusts the alternating current that switching frequency can produce different frequency as required, to adapt to the needs of different workpieces by the switch of drive plate control IGBT.On the series circuit of capacitor and transformer primary winding, be provided with instrument transformer, master control borad detects feedback signal according to instrument transformer and adjusts power frequency in real time, thereby improves thermal effectiveness.In the full bridge inverter of present technique scheme; Be equipped with the IGBT of two parallel connections among every group of IGBT; The IGBT of two parallel connections takes turns conducting, and this set mode has reduced the break-make frequency of single IGBT, and the peak frequency that produces alternating current is multiplied; Also reduce the loss of IGBT, improved the stability of a system.In order to protect IGBT, on the connection line of filter circuit and full bridge inverter, flow sensor was set, the output of crossing flow sensor is connected with master control borad, in case over-current phenomenon avoidance breaking circuit at once takes place, prevents beyond the mode.In addition, all be provided with water cooling plant in the present technique scheme on IGBT, transformer and the heater coil, adopt cooling water to cool off, this set-up mode cooling effectiveness is high, has improved the stability of equipment greatly.In sum, the heating device circuit of present technique scheme is simple in structure, failure rate is low, has the high stability and the efficiency of heating surface, can adjust the frequency of alternating current as required, adjusts easy and adjusting range is big.

Description of drawings

Fig. 1 is the structural representation of the utility model.

Fig. 2 is the electrical block diagram in the utility model control cubicle.

Fig. 3 is the set-up mode sketch map of full bridge inverter in the utility model.

Fig. 4 is the set-up mode sketch map of water cooling tube on the transformer coil in the utility model.

Fig. 5 is the transformer fe set-up mode sketch map of cooling water box in the heart in the utility model.

Fig. 6 is a plurality of transformer fe connected mode sketch map of cooling water box in the heart in the utility model.

Fig. 7 is the mode of the spiraling sketch map of the aqueduct that is connected with the cooling water box in the utility model.

Fig. 8 is the set-up mode sketch map of cooling collar on the heater coil in the utility model.

Mark among the figure: 1, control cubicle, 2, capacitor, 3, transformer, 4, heater coil, 5, master control borad, 6, driving transformer; 7, drive plate, 8, power supply, 9, full bridge inverter, 10, first groups of IGBT, 11, second groups of IGBT, 12, the 3rd groups of IGBT; 13, the 4th group of IGBT, 14, rectification circuit, 15, filter circuit, 16, instrument transformer, 17, cross flow sensor, 18, temperature sensor; 19, flow sensor, 20, cooling collar, 21, the transformer coil lead, 22, water cooling tube, 23, iron core; 24, cooling water box, 25, aqueduct, 26, lack detection circuit, 27, over-voltage detection circuit, 28, the sleeve pipe import; 29, sleeve pipe outlet, 30, the import of water box, 31, the outlet of water box, 32, the water pipe import, 32, pipe outlet.

Embodiment

As shown in the figure; A kind of electromagnetic induction heater that is used for the heating of metal workpiece; Comprise control cubicle 1, capacitor 2, transformer 3 and heater coil 4, the primary winding in the transformer 3 is connected in series with capacitor 2, and the secondary coil in the transformer 3 is connected in series with heater coil 4; Be provided with master control borad 5, driving transformer 6, drive plate 7, power supply 8 and four groups of IGBT in the control cubicle 1, the primary winding of capacitor 2 and transformer 3 is connected with the full bridge inverter 9 that four groups of IGBT form.As shown in Figure 3; The set-up mode of full bridge inverter 9 is: first group of IGBT 10 is connected with the 4th group of IGBT 13 with the primary winding serial connection back of capacitor 2 and transformer 3 successively; Second group of IGBT 11 is connected with the 3rd group of IGBT 12 with capacitor 2 serial connection backs with the primary winding of transformer 3 successively; First group of IGBT 10 and second group of IGBT 11 input also connect, and the 3rd group of IGBT 12 and the 4th group of IGBT 13 outputs also connect.Wherein, first group of IGBT 10 and the 4th group of IGBT 13 conducting simultaneously or shutoffs, second group of IGBT 11 and the 3rd group of IGBT 12 conducting simultaneously or shutoffs.Can in the series circuit of the primary winding of transformer 3 and capacitor 2, produce alternating current thus.The supply power mode of circuit is as shown in Figure 2, and power supply 8 is connected with full bridge inverter 9 with filter circuit 15 backs through rectification circuit 14 successively, and the control end of master control borad 5 is connected with the control utmost point of IGBT with drive plate 7 through driving transformer 6 successively.After the control signal of master control borad 5 is amplified through driving transformer 6, by conducting and the shutoff of drive plate 7 control IGBT.The set-up mode of control signal and the set-up mode of control circuit can adopt prior art.The circuit set-up mode of driving transformer 6 and drive plate 7 also can be implemented according to prior art.For real-time regulated feeds the power frequency and the bearing power of heater coil, on the series circuit of the primary winding of capacitor 2 and transformer 3, instrument transformer 16 is set, the output of instrument transformer 16 is connected with the feedback signal test side of master control borad 5.Master control borad 5 is controlled according to feedback signal.

As shown in Figure 3, in the described full bridge inverter 9, be equipped with the IGBT of two parallel connections among every group of IGBT.The IGBT of two parallel connections takes turns conducting, and this set mode has reduced the break-make frequency of single IGBT, and the peak frequency that produces alternating current is multiplied, and has also reduced the loss of IGBT, has improved the stability of a system.

Described filter circuit 15 was provided with flow sensor 17 with the connection line of full bridge inverter 9, and the output of crossing flow sensor 17 is connected with master control borad 5.Master control borad 5 control circuits turn-off when electric current surpasses set point, prevent danger or infringement.

In order to reduce the infringement that the IGBT heating brings, water cooling plant can be set on IGBT, be provided with water cavity in the water cooling plant, water cavity is provided with water inlet and delivery port, in water cavity, feeds recirculated water to reduce the temperature of IGBT.

In order to prevent that fortuitous event from causing the overheated infringement that brings of IGBT, temperature sensor 18 is set on IGBT, be used for monitoring in real time the temperature of IGBT.Water inlet at the water cooling plant of IGBT is provided with flow sensor 19, monitors the water flowing situation of water cooling plant in real time, prevents that accident from cutting off the water supply.The output of flow sensor 19 and temperature sensor 18 is connected with the test side of master control borad 5.

Because the power when metal works is heat-treated is very high, the equipment heating amount is big, and especially transformer 3 and heater coil 4 as can not in time lowering the temperature, will cause very big infringement to equipment, reduces useful life.As shown in Figure 8; Described heater coil 4 is arranged in the cooling collar 20; The coiling mode of cooling collar 20 is identical with the coiling mode of heater coil 4; End at cooling collar 20 is provided with sleeve pipe import 28, and the other end is provided with sleeve pipe outlet 29, in cooling collar 20, feeds recirculated water and cools.The lead of this type of cooling heater coil 4 directly contacts with cooling water, and cooling efficient is high.

Like Fig. 4, shown in Figure 5, described transformer 3 is provided with cooling device, and cooling device comprises the water cooling tube 22 that is enclosed within on the transformer coil lead 21 and is arranged on the cooling water box 24 on the iron core 23.The coiling mode of water cooling tube 22 is identical with the coiling mode of transformer coil lead 21, is provided with water pipe import 32 at an end of water cooling tube 22, and the other end is provided with pipe outlet 33.The type of cooling of this set mode and heater coil 4 is basic identical.On the cooling water box 24 of iron core 23, be provided with water box import 30 and water box outlet 31, feed recirculated water and lower the temperature.In order not influence the installation of iron core 23 in transformer coil is installed, can cooling water box 24 be arranged to two parts, two parts are separately positioned on the two ends up and down of iron core 23, and are interconnected.Water box import 30 is separately positioned on two parts up and down of cooling water box 24 with 31 of water box outlets.Because the magnetic flux in the transformer is very big, feed in the recirculated water of cooling water box 24 and very easily produce static, badly probably equipment or personnel are caused danger if handle.In order to address this problem, can be connected aqueduct 25 respectively with water box outlet 31 in the water box import 30 of cooling water box 24, supply water or drainings to cooling water box 24 through aqueduct 25, and with aqueduct 25 setting of spiraling in the form of a ring, the mode of spiraling is as shown in Figure 7.This set mode can effectively be eliminated the static in the cooling water, guarantees personal security.Owing to be typically provided with a plurality of iron cores in a transformer, in order to simplify being connected of cooling water box 24 and water system on the iron core 23.As shown in Figure 6, can the water box import 30 of cooling water box 24 on the water box outlet 31 adjacent iron cores 23 with another of cooling water box 24 on the iron core 23 be connected.Cooling water box on the iron core at transformer two ends is connected with water system through aqueduct respectively, the setting of spiraling equally in the form of a ring of the aqueduct here.

Described rectification circuit 14 is a bridge rectifier, and described filter circuit 15 is the RC filter circuit.

Described power supply 8 is provided with lack detection circuit 26 and over-voltage detection circuit 27, and the output of lack detection circuit 26 and over-voltage detection circuit 27 is connected with master control borad 5 respectively.

The present technique scheme, the alternating magnetic field that alternating current produces makes the induced current that produces sealing in the workpiece.The distribution of induced current on the workpiece cross section is very inhomogeneous, and work top layer current density is very high, inwardly reduces gradually, and this phenomenon is called kelvin effect.The electric energy of worksheet floor height density electric current changes heat energy into, and the temperature on top layer is raise, and promptly realizes the surface heating.Power frequency is high more, and workpiece surface is then big more with inner current density difference, and zone of heating is thin more.Cooling rapidly can realize surface hardening after the zone of heating temperature surpasses the critical point temperature of steel.The mode of employing induction heating can be to the workpiece localized heating, and workpiece deformation is little, has improved workpiece quality.The surface of the work quench-hardened case can be adjusted as required, is easy to control.The firing equipment of present technique scheme can be installed on the machining production line, is easy to realize mechanization and automation, is convenient to management, and can reduces transportation, practices thrift manpower, enhances productivity.

Claims (10)

1. electromagnetic induction heater that is used for the heating of metal workpiece; Comprise control cubicle (1), capacitor (2), transformer (3) and heater coil (4); It is characterized in that: the primary winding in the transformer (3) is connected in series with capacitor (2); Secondary coil in the transformer (3) is connected in series with heater coil (4); Be provided with master control borad (5), driving transformer (6), drive plate (7), power supply (8) and four groups of IGBT in the control cubicle (1); The primary winding of capacitor (2) and transformer (3) is connected with the full bridge inverter (9) that four groups of IGBT form; First group of IGBT (10) is connected with the 4th group of IGBT (13) with the primary winding serial connection back of capacitor (2) and transformer (3) successively; Second group of IGBT (11) is connected with the 3rd group of IGBT (12) with capacitor (2) serial connection back with the primary winding of transformer (3) successively, and first group of IGBT (10) and second group of IGBT (11) input also connect, and the 3rd group of IGBT (12) and the 4th group of IGBT (13) output also connect; Power supply (8) passes through rectification circuit (14) successively and is connected with full bridge inverter (9) with filter circuit (15) back, and the control end of master control borad (5) passes through driving transformer (6) successively and is connected with the control utmost point of IGBT with drive plate (7); Also be provided with instrument transformer (16) on the series circuit of the primary winding of capacitor (2) and transformer (3), the output of instrument transformer (16) is connected with the feedback signal test side of master control borad (5).

2. a kind of electromagnetic induction heater that is used for the heating of metal workpiece as claimed in claim 1 is characterized in that: in the described full bridge inverter (9), be equipped with the IGBT of two parallel connections among every group of IGBT.

3. a kind of electromagnetic induction heater that is used for the heating of metal workpiece as claimed in claim 1; It is characterized in that: described filter circuit (15) was provided with flow sensor (17) with the connection line of full bridge inverter (9), and the output of crossing flow sensor (17) is connected with master control borad (5).

4. a kind of electromagnetic induction heater that is used for the heating of metal workpiece as claimed in claim 1, it is characterized in that: described IGBT is provided with water cooling plant, is provided with water cavity in the water cooling plant, and water cavity is provided with water inlet and delivery port.

5. a kind of electromagnetic induction heater that is used for the heating of metal workpiece as claimed in claim 4; It is characterized in that: described IGBT is provided with temperature sensor (18); The water inlet of said water cooling plant is provided with flow sensor (19), and the output of flow sensor (19) and temperature sensor (18) is connected with the test side of master control borad (5).

6. a kind of electromagnetic induction heater that is used for the heating of metal workpiece as claimed in claim 1; It is characterized in that: described heater coil (4) is arranged in the cooling collar (20); The coiling mode of cooling collar (20) is identical with the coiling mode of heater coil (4); End at cooling collar (20) is provided with sleeve pipe import (28), and the other end is provided with sleeve pipe outlet (29).

7. a kind of electromagnetic induction heater that is used for the heating of metal workpiece as claimed in claim 1; It is characterized in that: described transformer (3) is provided with cooling device; Cooling device comprises the water cooling tube (22) that is enclosed within on the transformer coil lead (21) and is arranged on the cooling water box (24) on the iron core (23); The coiling mode of water cooling tube (22) is identical with the coiling mode of transformer coil lead (21); End at water cooling tube (22) is provided with water pipe import (32), and the other end is provided with pipe outlet (33); Cooling water box (24) is provided with water box import (30) and water box outlet (31).

8. a kind of electromagnetic induction heater that is used for the heating of metal workpiece as claimed in claim 7; It is characterized in that: described cooling water box (24); Its water box import (30) and water box outlet (31) is connected with aqueduct (25) respectively, aqueduct (25) setting of spiraling in the form of a ring.

9. a kind of electromagnetic induction heater that is used for the heating of metal workpiece as claimed in claim 1 is characterized in that: described rectification circuit (14) is a bridge rectifier, and described filter circuit (15) is the RC filter circuit.

10. a kind of electromagnetic induction heater that is used for the heating of metal workpiece as claimed in claim 1; It is characterized in that: described power supply (8) is provided with lack detection circuit (26) and over-voltage detection circuit (27), and the output of lack detection circuit (26) and over-voltage detection circuit (27) is connected with master control borad (5) respectively.

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