KR100681135B1 - An electrical type-laundry dryer - Google Patents

Abstract

An electrical type laundry dryer is provided to allow a power generation unit to generate lamp power, operation voltage, and coil driving voltage by applying the most suitable load to a half bridge converter according to the operation of a lamp driving unit. An electrical type laundry dryer comprises: a general power generating unit(31) for generating coil driving voltage by rectifying lamp power after generating lamp power from AC power applied from the outside through a half-bridge converter, and generating operation voltage by lowering coil driving voltage; a switch controlling unit(40) having plural switches(SW1, SW2, SW3, SW4), and verifying voltage of a signal according to a kind of the switch selected by a user; a lamp driving unit(32) having a lamp, and lighting the lamp by using lamp power when receiving a lamp driving signal; and a controlling unit for outputting the generated lamp driving signal into the lamp driving unit when receiving a switch signal having voltage corresponding to the lamp driving signal, after setting voltage of the switch signal respectively corresponding to plural control signals. The lamp driving unit comprises a dummy circuit having minimum load generating coil driving voltage; and a switching unit for allowing lamp power to flow through the lamp so as to apply the lamp to load of the half bridge converter when receiving the lamp driving signal, and applying the dummy circuit to load of the half bridge converter when not receiving the lamp driving signal.

Description

Electronic laundry drying equipment {an electrical type-laundry dryer}

1 is an external view of a conventional electronic laundry drying apparatus.

2 is an internal block diagram of a conventional electronic laundry drying apparatus.

3 is an internal block diagram of an electronic laundry drying apparatus according to the technique of the present invention.

4 is a detailed circuit diagram of the electronic laundry drying apparatus of FIG.

5 is an external view of an electronic laundry drying apparatus according to the technology of the present invention.

<Description of Symbols for Main Parts of Drawings>

31: integrated power generating unit 32: lamp driving unit

33: height adjustment part 34: fan drive part

35: CPU 40: switch control panel

321: lamp portion 332: dummy portion

323: switching unit

The present invention relates to an electronic laundry drying apparatus, and in particular, connects the main body and the switch operation unit of the electronic laundry drying apparatus spaced apart from each other by one signal line pair, and supplies various power sources required for the operation of the electronic laundry drying apparatus. The present invention relates to an electronic laundry drying apparatus capable of generating through a generating circuit.

The electronic laundry drying apparatus attaches the main body 10 having various driving devices (ie, height adjusting motor, lamp, fan motor, etc.) to the ceiling of a building as shown in FIG. By adjusting the height, it is an apparatus that increases the maximum use efficiency of the space for drying the laundry.

However, when the main body 10 is attached to the ceiling of the building as shown in FIG. 1, since the user's access is difficult, the switch operation unit 20 is generally separated from the main body 10 so that the user can easily access the side of the building. The main body 10 and the switch operation unit 20 are electrically connected to each other through separate signal lines.

2 is a block diagram illustrating an internal laundry drying apparatus according to the present invention. Referring to FIG. 2, the electronic laundry drying apparatus includes an operating voltage generator 11 and a lamp provided in the main body 10. Lamp switch SW1 provided in the power supply unit 12, lamp drive unit 13, height adjustment unit 14, fan drive unit 15, and CPU 16, and switch operation unit 20, and height increase switch ( SW2), height lowering switch SW3, and fan switch SW4.

The operating voltage generator 11 generates an operating voltage VDD having a voltage for driving the CPU 16 by full-wave rectifying and filtering AC power applied from the outside, and the lamp power generator 12. Variates the operating frequency of the AC power source AC and drops the voltage to generate the lamp power source LAC for driving the lamp driver 11.

In this case, the lamp power generator 12 is generally implemented as a half-bridge converter. The half-bridge converter is used only when the lamp driver 13 is driven and the load of the lamp is applied. LAC) has an operating characteristic that can occur. That is, the lamp power generator 12 according to the related art may generate the lamp power LAC only when the lamp driver 13 is driven.

However, the operating voltage generator 11 should always generate and provide the operating voltage VDD to the CPU 16 regardless of whether or not the lamp driver 13 is driven. Accordingly, the conventional electronic laundry drying apparatus separates the operating voltage generator 11 and the lamp power generator 12 so that the operating voltage VDD is always provided, and the lamp power source LAC is provided with the lamp driver 13. It had to be provided only when it worked.

The lamp driver 13 includes a lamp (not shown) for performing an illumination function and a laundry drying function, and upon receiving the lamp driving signal, forms a current path between the lamp and the lamp power source LAC to turn on the lamp.

The height adjusting unit 14 includes a height adjusting motor (not shown) for adjusting the height of the drying plate 101, and upon receiving a height rising signal, forms a first current path between the height adjusting motor and the AC power source AC. When the height adjusting motor raises the height of the drying plate 101 and receives the height lowering signal, a height adjustment motor forms a second current path between the height adjusting motor and the AC power source AC so that the height adjusting motor increases the height of the drying plate 101. Let's lower.

The fan drive unit 15 includes a fan motor (not shown) for rotating the blower fan, and upon receiving the fan drive signal, forms a current path between the fan motor and the AC power source (AC) so that the fan motor rotates the blower fan. do.

The CPU 16 is connected one-to-one with each of the plurality of switches SW1, SW2, SW3, and SW4 provided in the switch operating unit 20, so that one of the plurality of switches SW1, SW2, SW3, and SW4 is switched. When the signal is generated, a control signal for driving the driving device corresponding to the switch, that is, the lamp driving unit 13, the height adjusting unit 14, or the fan driving unit 15 is generated.

The switch operation unit 20 includes a lamp switch SW1, a height raising switch SW2, a height lowering switch SW3, and a fan switch SW4, which respectively generate a switch signal having a predetermined current (or voltage). When the user selects one switch, a switch signal corresponding to the switch is generated and provided to the CPU 16.

As such, the CPU 16 of FIG. 2 and the plurality of switches SW1 to SW4 in the switch operation unit 20 are connected in parallel, and the CPU 16 is a switch signal transmitted to each of the plurality of switches SW1 to SW4. In response to each of these, the type of control signal to be generated was determined.

In order to transmit the switch signals of the plurality of switches SW1, SW2, SW3, and SW4 to the CPU 16, the switch operation unit 20 had to have signal lines corresponding to the number of switches.

However, since the signal line for connecting between the CPU 16 and the switch control unit 20 must be installed over the ceiling and the wall of the building as shown in FIG. 1, the signal line for connecting between the CPU 16 and the switch control unit 20 is provided. The greater the number of signal lines, the more difficult the wiring of the signal lines is, and the disadvantages of harming the aesthetics of the building. Also, in the worst case, signal interference between adjacent signal lines may occur, and a switch signal having wrong information may be applied to the CPU.

In addition, the conventional electronic laundry drying apparatus must include a component performing a similar role as described above, that is, an operating voltage generator 11 for generating an operating voltage and a lamp power generator 12 for generating a lamp power. Since it had to be provided separately, there was a problem that the circuit of the electronic laundry drying apparatus was unnecessarily increased.

An object of the present invention is to reduce the signal line for connecting between the main body and the switch operation unit of the electronic laundry drying apparatus spaced apart from each other, and to simplify the circuit configuration of the main body.

Electronic laundry drying apparatus of the present invention for achieving the above object generates a lamp power from the AC power applied from the outside through a half-bridge converter, and then full-wave rectified lamp power to generate a coil drive voltage, coil drive voltage And a lamp operating signal including an integrated power generating unit configured to generate an operating voltage by lowering the voltage, a switch operating unit including a plurality of switches, and varying a voltage of the switch signal according to the type of switch selected by the user, and a lamp. When receiving a lamp, the lamp driving unit to turn on the lamp by using the lamp power, and the voltage of the switch signal corresponding to each of the plurality of control signals, and after the switch signal having a voltage corresponding to the lamp driving signal is received, the lamp driving And a controller for generating a signal and outputting the signal to the lamp driver. A dummy circuit having a minimum load capable of generating a coil drive voltage and a lamp power flowing through the lamp when the lamp drive signal is received, applying the lamp to the load of the half-bridge converter, and not receiving the lamp drive signal. The apparatus may further include a switching unit configured to apply a dummy circuit to a load of the half-bridge converter.

The switch operation unit includes a plurality of resistors connected in series between the operating voltage and the ground voltage, and a plurality of switches connected between each of the plurality of resistors and the ground voltage, and the switch operation unit includes a plurality of switches by the user. When one is selected, the switch signal is generated by distributing the operating voltage through the resistors connected between the selected switch and the operating voltage.

Hereinafter, with reference to the accompanying drawings illustrating an automatic laundry drying apparatus of the present invention.

3 is a block diagram illustrating an internal laundry drying apparatus according to the present invention. Referring to FIG. 3, the electronic laundry drying apparatus includes an integrated power generator 31 and a lamp provided in the main body 30. The driving unit 32, the height adjusting unit 33, the fan driving unit 34, and the CPU 35, the lamp switch SW1, the height raising switch SW2, and the height lowering switch SW3 provided in the switch operation unit 40. ), And a fan switch SW4. In this case, the lamp driver 32 includes a lamp unit 321, a dummy unit 322, and a switching unit 323.

The integrated power generator 31 generates all operating voltages for driving the laundry drying apparatus from the AC power source AC. That is, as shown in the lamp power generator 12 of FIG. 2, a half-bridge converter (not shown) is provided to vary the frequency of the AC power source AC and drop the voltage to generate the lamp power source LAC, and then the lamp power source. The LAC is again propagated to generate a coil driving voltage VPP, and the coil driving voltage VPP is dropped again to generate an operating voltage VDD.

At this time, preferably, the lamp power source LAC has a higher frequency and lower voltage than the AC power source AC. In addition, the coil driving voltage VPP is a voltage for controlling the state of the relay switch to be described below, which will be described in detail later.

The lamp unit 321 in the lamp driver 32 includes at least one lamp that is turned on when the lamp power source LAC is applied, and the dummy part 322 has a minimum load for generating a coil drive voltage VPP. And a circuit element having a circuit element, and the switching unit 323 forms a current path between the lamp unit 321 and the lamp power source LAC when receiving the lamp driving signal, and the dummy unit 322 when the lamp driving signal is not received. Form a current path between the lamp power supply (LAC). That is, the lamp driver 32 applies a load of the lamp unit 321 to the half-bridge converter in the integrated power generation unit 31 when the lamp is driven, and the dummy part to the half-bridge converter when the lamp is not driven. A load of 322 is applied.

Accordingly, the half-bridge converter generates a lamp power source LAC for driving the lamp according to the load of the lamp when the lamp is driven, and the coil driving voltage VPP according to the load of the dummy part 322 when the lamp is not driven. And a lamp power LAC generating the driving voltage VDD.

As described above, according to the present invention, the lamp driver 32 further includes a dummy part 322 in addition to the lamp part 321 to generate the lamp power source LAC in the half-bridge converter, as well as the coil driving voltage VPP. By applying a load for generating a), the conventional operating voltage generator 11 and the lamp power generator 12 is implemented as one integrated power generator 31.

The height adjusting unit 33 includes a height adjusting motor (not shown) for adjusting the height of the drying plate 101, and upon receiving a height rising signal, forms the first current path between the height adjusting motor and the AC power source AC. The height adjusting motor causes the height of the drying plate 101 to rise, and when the height lowering signal is received, a second current path is formed between the height adjusting motor and the AC power source AC so that the height adjusting motor of the drying plate 101 is formed. Lower the height.

The fan drive unit 34 includes a fan motor (not shown) for rotating the blower fan, and upon receiving the fan drive signal, forms a current path between the fan motor and the AC power source (AC) so that the fan motor rotates the blower fan. do.

The CPU 35 has a program for controlling the overall operation of the laundry drying apparatus, and when the user requests a specific operation through the switch operation unit 40, the component that performs the operation requested by the user, that is, the lamp driving unit 32, a control signal for driving the height adjustment unit 33 and the fan drive unit 34 is generated.

In particular, the CPU 35 receives only one switch signal from the switch operation unit 40, so that the user can determine which switch is selected by the user according to the voltage level of the switch signal. The CPU 35 presets a voltage corresponding to each of the control signals (that is, the lamp driving signal, the height rising signal, the height falling signal, and the fan driving signal) in advance, and when the switch signal is transmitted from the switch operation unit 40, Generate a control signal corresponding to the voltage of the switch signal.

The switch operation unit 40 includes a lamp switch SW1, a height rising switch SW2, a height falling switch SW3, and a fan switch SW4 having different resistances and connected in parallel between an operating voltage and a ground voltage. . When the user selects one of the plurality of switches, the operating voltage is divided according to the resistance of the selected switch, and then a switch signal having the divided voltage is generated and output to the CPU 35. That is, the switch operation unit 40 outputs only one switch signal, and varies the voltage of the switch signal according to the type of the selected switch.

4 is a detailed circuit diagram of the electronic laundry drying apparatus of FIG.

Referring to FIG. 4, the integrated power generator 31 may change the frequency of the AC power source AC and drop the voltage to generate a lamp power source LAC that generates a lamp power source LAC. ) The operating voltage VDD is generated by dropping the generating circuit HBC, the coil driving voltage generation circuit VPPC generating the coil driving voltage by propagating the lamp power source LAC, and the coil driving voltage VPP. And an operating voltage generation circuit VDDC.

The half-bridge converter HBC includes first bridge diodes D11 to D14 for full-wave rectification of the AC power source AC, and first and second capacitors for dividing the output voltages of the first bridge diodes D11 to D14. (C1, C2), the first and second transistors Q1, Q2, and the first and second transistors Q1, which alternately output the output voltages of the first bridge diodes D11 to D14 according to the control clock signals. And a transformer T for transforming the power output through Q2) to generate the lamp power LAC, and then outputting the lamp power to the first and second output nodes n1 and n2.

In addition, the coil driving voltage generation circuit VPPC is connected to the first and second output nodes n1 and n2 of the transformer T, and the second bridge diode D21 for full-wave rectifying the lamp power source LAC of the transformer T. D24 and capacitors for filtering the output voltages of the second bridge diodes D21 to D24 to generate the coil driving voltage VPP, and resistors C3, C4, and R1, and an operating voltage generation circuit VDDC. ) Includes diodes, resistors, and capacitors ZD, R2, and C5 that drop the coil drive voltage VPP to generate an operating voltage VDD.

The lamp unit 321 of the lamp driver 32 includes a first lamp LM1 and a second lamp LM2, a first lamp LM1, and a second lamp LM2 that are turned on when the lamp current LAC is applied. A capacitor C7 and a resistor R4 are provided to prevent contact sparks in the furnace, and the dummy part 322 has a minimum load value at which the half-bridge converter HBC can generate the coil driving voltage VPP. That is, a capacitor C6 having an impedance value) and a resistor R3 are provided.

When the lamp driving signal is output from the first output terminal out1 of the CPU 35, the switching unit 323 allows a current corresponding to the coil driving voltage VPP to flow through the first coil RY1. When the first coil RY1 and the first coil RY1 which generate electromagnetic waves according to the inverter I1, the current corresponding to the coil driving voltage VPP, the lamp power source LAC is the first or second The first relay switch RSW1 for switching the lamp power LAC to flow through the capacitance C6 and the resistor R3 when flowing through the lamps LM1 and LM2 and the first coil RY1 fails to generate electromagnetic waves. It is provided.

In this case, the first relay switch RSW1 is a switch implemented by a spring method in which the connection state is automatically restored according to whether electromagnetic is applied. That is, the spring of the switch is basically connected to the second contact point, the spring is connected to the first contact point when the electromagnetic is applied, the spring is connected to the second contact point again if the electromagnetic is not applied.

The height adjusting unit 33 rotates in a forward direction when the AC power source AC flows through the first terminal and the second terminal (ie, flows through the first current path), and the AC power source AC rotates in the first terminal and the third terminal. A height adjustment motor HCM rotating in the reverse direction when flowing through the terminal (ie, flowing through the second current path), a height rising signal output from the second and third output terminals out2 and out3 of the CPU 35; The second and third inverters I2 and I3 and the coil driving voltage (C2) so that a current corresponding to the coil driving voltage VPP flows through the second and third coils RY2 and RY3 in response to the height falling signal. When the second and third coils RY2 and RY3 and the second coil RY2 each generate electromagnetic waves according to a current corresponding to VPP), the AC power source AC generates the first When the second relay switch RSW2 and the third coil RY3 which flow through the first terminal and the second terminal generate electromagnetic, the AC power is high. And a third relay switch (RSW3) to flow through to the first terminal and the third terminal of the adjusting motor (HCM).

The fan driver 34 drives the fan output from the fan motor FM and the fourth output terminal out4 of the CPU 35 to perform a rotation operation when the AC power AC flows through the first terminal and the second terminal. A fourth inverter I4 for causing a current corresponding to the coil driving voltage VPP to flow through the fourth coil RY4 in response to the signal, and a fourth generating electromagnetic wave according to the current corresponding to the coil driving voltage VPP. The fourth coil RY4 and the fourth coil RY4 are provided with electromagnetic waves, and the fourth relay switch RSW4 allows AC power to flow through the first terminal and the second terminal of the fan motor FM. do.

The switching operation unit 40 includes a plurality of resistors R5 to R8 connected in series between the operating voltage VDD and the ground VSS, and a plurality of resistors R5 to R8 and a ground voltage VSS, respectively. A plurality of switches SW1 to SW4 that are connected to each other and share the operating voltage VDD through resistors connected between the operating voltage VDD and the ground VSS at turn-on, and the voltage-divided operation by the turned-on switch Resistors and capacitors R9 and C8 for filtering the voltage VDD to generate a switch signal and transmitting the generated switch signal to the input terminal in of the CPU 35.

Hereinafter, referring to Figure 4, the operation of the laundry drying apparatus of the present invention will be described.

First, the integrated power generator 31 generates a lamp power source LAC having a higher frequency and a smaller voltage than the AC power source AC through the half-bridge converter HBC.

Then, the second diode bridges D21 to D24 propagate the lamp power source LAC again, and then smooth the current through the capacitors and the resistors C3, C4, and R1 to generate the coil driving voltage VPP, and the diode, The resistor and capacitors ZD, R2, and C5 drop the coil drive voltage VPP again to generate an operating voltage VDD.

In this state, when the user selects one of the plurality of switches SW1 to SW4 provided in the switch operation unit 40, the voltage of the switch signal is changed according to the resistance of the selected switch.

That is, the switch operating unit 40 varies the voltage of the switch signal to the operating voltage VDD when the lamp switch SW1 is selected, and when the height raising switch SW2 is selected, " operating voltage VDD × R6. / (R5 + R6)) ", and when the height lowering switch SW3 is selected, the operation voltage VDD x (R6 + R7 / (R5 + R6 + R7))" is changed to the fan switch ( At the time of selection of SW4), it is varied to " operating voltage VDD × (R6 + R7 + R8 / (R5 + R6 + R7 + R8)) ”.

Accordingly, when the CPU 35 receives the switch signal having the operating voltage VDD, the CPU 35 generates a lamp driving signal, and the first inverter I1, the first coil RY1, and the first relay switch in the lamp driving unit 32. RSW1 causes the lamp power source LAC to flow through the first or second lamps LM1 and LM2 in response. Then, the first lamp LM1 and the second lamp LM2 are alternately turned on in response to the lamp power source LAC, and the half-bridge converter HBC loads the first and second lamps LM1 and LM2. It generates the lamp power (LAC) continuously.

However, when the CPU 35 receives a switch signal having a voltage other than the operating voltage VDD, the generation of the lamp driving signal is stopped, and the first inverter I1, the first coil RY1, In response, the first relay switch RSW1 causes the lamp power LAC to flow through the capacitor and the resistors C6 and R3 of the dummy part 322. Then, the first lamp LM1 and the second lamp LM2 are turned off because the lamp power source LAC is not applied, but the half-bridge converter HBC is turned off instead of the loads of the first and second lamps LM1 and LM2. The lamps are continuously generated by applying the loads of the capacitors and resistors C6 and R3.

If the voltage of the switch signal is " operating voltage VDD × (R6 / (R5 + R6)) ", the CPU 35 generates a height rising signal and the second inverter I2 in the height adjusting section 33. , The second coil RY2, and the second relay switch RSW2 cause the AC power AC to flow through the first terminal and the second terminal of the height adjustment motor HCM in response to the height rising signal. The regulating motor HCM rotates in the forward direction in response to raising the drying rack 101.

If the voltage of the switch signal is " operating voltage VDD × (R6 + R7 / (R5 + R6 + R7)) ", the CPU 35 generates a height falling signal, and the third inverter in the height adjusting section 33 is generated. I2, the third coil RY3, and the third relay switch RSW3 allow the AC power AC to flow through the first terminal and the third terminal of the height adjustment motor HCM in response to the height falling signal. In response, the height adjustment motor HCM rotates in the reverse direction to lower the drying rack 101.

Finally, when the voltage of the switch signal is " operating voltage VDD ×× (R6 + R7 + R8 / (R5 + R6 + R7 + R8)) ", the CPU 35 generates a fan drive signal, and the fan driver 34 In the fourth inverter I4, the fourth coil RY4, and the fourth relay switch RSW4 in the AC power supply, the AC power source LAC is connected to the first terminal and the second terminal of the fan motor FM in response to the fan driving signal. And the fan motor FM rotates the blower fan in response.

As described above, the switch operation unit 40 of the present invention only changes the voltage of the switch signal according to the switch type selected by the user. In this regard, the switch operation unit 40 may always have only one signal pair regardless of the number of switches provided therein.

Accordingly, as shown in FIG. 5, the number of signal lines that must be installed across the ceiling and the wall of the building is drastically reduced, thereby minimizing the aesthetics of the building, and between the switch control unit 40 and the CPU 35, that is, the main body. Make it easier to install signal lines for connection.

In addition, the optimum load is applied to the half-bridge converter for generating the lamp power according to the operation state of the lamp driver so that the integrated power generator generates both the lamp power, the operating voltage, and the coil driving voltage. Therefore, it is possible to perform all the functions of the operating voltage generator and the lamp power generator, which are separately provided in the related art, in one integrated power generator.

Although the above has been described with reference to a preferred embodiment of the present invention, those skilled in the art will be variously modified and changed within the scope of the invention without departing from the spirit and scope of the invention described in the claims below. I can understand that you can.

In the electronic laundry drying apparatus of the present invention, regardless of the number of switches provided in the switch operating unit, the signal operating unit and the main body can be connected at any time through one signal line pair. Keep it simple.

In addition, the optimum load is applied to the half-bridge converter provided in the integrated power generation unit according to the operation state of the lamp driving unit so that the integrated power generation unit generates both the lamp power supply, the operating voltage, and the coil driving voltage. This reduces the number of power generation circuits provided in the electronic laundry drying apparatus to simplify the circuit configuration.

Claims (6)

After generating the lamp power from the AC power applied from the outside through the half-bridge converter, the lamp power is full-wave rectified to generate a coil driving voltage, and the coil driving voltage is dropped to generate the integrated power generating the operating voltage. part; A switch operation unit having a plurality of switches and varying a voltage of a switch signal according to a type of switch selected by a user; A lamp driving unit including a lamp and lighting the lamp by using the lamp power when receiving a lamp driving signal; And After setting the voltage of the switch signal corresponding to each of the plurality of control signals, when the switch signal having a voltage corresponding to the lamp driving signal is received, a control unit for generating the lamp driving signal and outputs to the lamp driving unit Equipped, The lamp driving unit A dummy circuit having a minimum load capable of generating the coil drive voltage; And When the lamp driving signal is received, the lamp power flows through the lamp to apply the lamp to the load of the half-bridge converter, and when the lamp driving signal is not received, the dummy circuit is connected to the half-bridge converter. Electronic laundry drying apparatus further comprises a switching unit for applying a load of. The method of claim 1, wherein the switch operation unit A plurality of resistors connected in series between the operating voltage and the ground voltage; And A plurality of switches connected between each of the plurality of resistors and the ground voltage, The switch operation unit And when one of the plurality of switches is selected by a user, generating the switch signal by distributing the operating voltage through resistors connected between the selected switch and the operating voltage. The method of claim 1, wherein the dummy circuit An electronic laundry drying device comprising at least one capacitor and a resistor. The method of claim 1, wherein the switching unit A coil for generating electromagnetic waves when a current corresponding to the coil driving voltage flows; A driver for allowing a current corresponding to the coil driving voltage to flow through the coil when the lamp driving signal is received; And And a relay switch configured to allow the lamp power to flow through the lamp when the coil generates electromagnetic waves, and to flow the lamp power through the dummy circuit when the coil does not generate electromagnetic waves. Drying device. The method of claim 4, wherein the relay switch Electronic laundry drying apparatus, characterized in that the spring-type switch in which the connection state is determined according to the application of electromagnetic. The method of claim 4, wherein the lamp is Electronic laundry drying apparatus, characterized in that at least one.

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