DE3616480A1 - Circuit for carrying out the method for an electrical load which is supplied from a three-phase voltage source - Google Patents

Abstract

The invention relates to a circuit for carrying out the method according to the main claim of Patent 3540830.8 (DE part of the PCT application PCT DE 8500474). The circuit is used in the case of a continuous-flow heater which is supplied from a three-phase network, the continuous-flow heater having resistors which are connected at least between two external conductors of the network. The invention is based on arranging two resistors (K21, R22) (which produce different powers in the event of continuous switching on) in parallel and in each case in series with an electronic switch (TR21, TR22) between the conductors (L1, L3) of a first pair of external conductors, the switches being operated in a periodically burst-fire controlled manner and at a duty ratio of one half, and only one resistor in each case being instantaneously connected to voltage, and a further resistor (FR1) being arranged in series with a further switch (TR1) between the conductors (L1, L3) of a different pair of external conductors, which further switch (TR1) is operated in periodically burst-fire controlled manner at a variable duty ratio. <IMAGE>

Description

The present invention relates to a circuit for performing of the method according to the main claim of the patent (DE part of the PCT application PCT-DE 85 00 474) for one from a three-phase voltage source fed electrical consumers, especially electrical flowers hot.

The invention is based on an older method, the essential Characteristic is that on two outer conductors of an AC voltage source two unequal resistors are connected in parallel and each arranged in series with an electronic switch are. To represent partial services between zero and the at Permanent activation of both resistors resulting maximum power is fine from this process emerged the two electronic switches perio to operate vibration package controlled in such a way that when the larger resistor is turned on, the smaller one is turned off is and vice versa. To a relatively large with this circuit arrangement To be able to cover the performance range, it is necessary that one connect at least one additional resistor in parallel to both resistors must be operated analog.

The object of the invention is the method with regard to its To further develop application for an electric instantaneous water heater.

Accordingly, the invention resides in the characterizing features of the main subject saying.

Further embodiments are the subject of the subclaims and, together with further advantageous features, are the subject of the following description, which describes an exemplary embodiment of the invention with reference to FIGS. 1 to 9 with the aid of a table. It shows

Fig. 1 shows a basic circuit,

Fig. 2 diagrams,

Fig. 3 shows a circuit for a three-phase load,

Fig. 4 is an electric water heater as a schematic representation,

Fig. 5 shows a first circuit for the water heater,

Fig. 6 shows a second circuit for the water heater and the

FIGS. 7 to 8 diagrams.

The circuit is based on the basic idea to represent a certain to use several unequal partial resistances, of which at Operation on AC or three-phase voltage one or more with Schwin supply package controls are operated, the mean of the one performance as the sum of the mean values of the benefits to the counter stands results. When operating on DC voltage, replace the Schwin package control pulse width controls.

Fig. 1 shows a circuit for explaining the basic principle of the inven tion.

To the outer conductors L ₁ , L ₂ , two resistors R ₁ and R _{2 are} closed via triacs.

A power P ₁ , for example P ₁ = 1.75 kW, drops off at resistor R ₁ when fully switched on. The resistor R ₂ is designed so that the power P ₂ drops when it is fully switched on, which is twice as large as P ₁ , that is P ₂ = 2 P ₁ , for example P ₂ = 3.5 kW.

Fig. 2 shows the process of power adjustment.

The range of services available from P = 0 to P = P ₁ is at off R ₂ set by periodic oscillation packet controller of R ₁ having different duty cycles, the duty cycle T is obtained as the sum of the switch-on times t _A, based on the period duration t _p.

In the field of power P = P ₁ to P = P ₂ = 2 P ₁ of the resistor R ₂ is operated permanently with periodic burst control of the duty cycle T = 0.5, so that in it a mean power of P _2/2 = P ₁ falls off. The resistor R ₁ is operated as in the abovementioned power range with vibration package control, so that the power can be finely adjusted by different duty cycles for R ₁ in the specified power range.

In the range of the power P = P ₂ to P = P ₁ + P ₂ = 3 P ₁ , the resistor R _{2 is switched on} permanently and the resistor R _{1 is operated} with a vibration package control, so that a fine adjustment is made by different duty cycles.

When using vibration packet control for R ₁ or R ₂ , only full-wave control is used and switched at zero current. The procedure according to the invention is such that

• a) the smallest switch-on time or the smallest switch-off time Network period (20 ms),
• b) the highest possible switching frequency is achieved to the mains return to minimize effects (flicker). For this, a longer switch-on time or a longer switch-off time in several short switch-on times or switch-off times of a network period divided,
• c) when simultaneously applying vibration packet control to R ₁ and R _2, the switch-on times for R _{1 are} identical to switch-off times for R ₂ and vice versa, in order to minimize the network effects (flicker),
• d) the resistor R ₂ and the power P ₂ are selected so that the permissible flicker level is not exceeded by vibration packet control with a pulse duty factor T = 0.5 and a switch-on or switch-off time of one network period.

In the example in FIG. 2, the period t _p = 5 is 20 ms = 120 ms. This means that a minimum duty cycle of T = 20 ms / 120 ms = 1/6 can be achieved. With the specified powers P ₁ = 1.75 kW and P ₂ = 3.5 kW, the total power P can thus be set in steps of approx. 290 W from 0 to 5.25 kW.

The following comments are essential: The power P ₂ need not be exactly twice as large as P ₁ . To display larger power ranges, additional resistors can be switched on or off. the resistors R ₁ and R _{2 can} also be operated on different outer conductors of a three-phase system.

Fig. 3 shows the application of the invention in an electric flow heater with a total power of 21 kW.

The resistors R ₁ and R ₂ are identical to those of FIG. 1, but are due to different outer conductors.

As a result, a switch-on process of R ₁ cannot be realized exactly at the same time as a switch-off process of R ₂ when switching at the zero point.

The instantaneous water heater can be designed such that a power of 3.5 kW at R ₀ , a power of 1.75 at R _1, a power of 3.5 at R ₂ , 5.75 at R ₃ and on R ₄ drops from 7 kW.

When the device is switched on, the power at R ₀ (3.5 kW) is always available. In the range between 3.5 kW and 21 kW, the power can be set in steps of approximately 290 W by operating R ₁ and R _{2 in} accordance with FIG. 2 and resistors R ₃ and R ₄ which are switched on or off.

Favorable network perturbations result from the specified connection sequence.

The following remarks apply to the circuit according to FIG. 3: The overall performance can deviate from 21 kW. The distribution of R ₃ and R ₄ can be chosen differently. The resistors can be chosen to be smaller overall (or larger) with the same conditions. The application can be done for any electrical devices, both single-phase according to Fig. 1 or three-phase. The circuit can also be used for DC voltage supply and also for complex resistors.

For the above, the following applies: A smaller resistance means a resistance with smaller power that can be generated.

When operating on a three-phase system, simultaneous switching means switching in succession at the current zero crossing. Any electrical loads shown in FIG. 4, in particular a water heater, has a channel body 1, which is made of plastic and has a meandering be continuous water channel 2.

The water channel is connected to a feeding cold water supply line 3 and to a hot water supply line 4 , the latter being provided with a tap valve 5 .

There are three channels 6 , each heated by a resistor R 1 , R 21 , R 22 , in the channel body 1 , which are hydraulically connected in series in the water.

A vibration packet controller 7 is assigned to the resistors.

It is possible to measure the hot water outlet temperature by means of a temperature sensor arranged in the channel 4 and to control the vibration output package 7 via the vibration package control 7 , so that a certain outlet temperature regardless of the level of the outputted resistors R 1 , R 21 and R 22 Cold water inlet temperature and regardless of the flow rate it is aimed at. It is also possible to control the power output to the resistors at a given throughput and estimated or measured cold water inlet temperature so that a predeterminable hot water temperature is sufficient.

The associated basic circuit is shown in FIG. 5.

A first line 8 , which leads to a first branch point 9 and a second branch point 10 , is connected to a first outer conductor L 1 of a feeding three-phase voltage network with a chained outer conductor voltage of 380 V. From the first branch point 9 a first branch 11 branches off, which consists of a series connection of an electronic switch Tr 22 (for example a triac) and the resistor R 22 . The branch 11 is on the free side at a junction 12 ruled out, which is connected via a line 13 to the outer conductor L 3 . Between the branch points 10 and 12 , a second branch 14 is connected, which consists equally of an electronic switch Tr 21 and the resistor R 21 . The resistors R 21 and R 22 are different Lich and the resistor R 21 is designed so that there is a power P 21 on it when the associated triac Tr 21 is switched on continuously. The power P 22 at the associated resistor R 22 which results when the triac Tr 22 is switched on continuously is dimensioned such that it is approximately twice as large as the power P 21 . One strives for the leap in performance of two between the two, if possible, but it will not necessarily have to be achieved due to tolerances.

A further line 15 leads from the outer conductor L 2 to a third branch 16 , which likewise consists of the series connection of the resistor R 1 with its associated triac Tr 1 and, on the other hand, is connected to the branching point 10 . The resistance R 1 is selected so that when the triac Tr 1 is switched on continuously, the power P 1 that can be generated on it is approximately half the power P 21 .

The design of the resistors R 1 , R 12 , R 22 is to be carried out in such a way that the total power in the entire range from 0 to the total power of P 1 + P 21 + P 22 can be finely adjusted. This is the case when P 1 minds least P 21/2 and 22 for P <2 * P is the power P 1, at least (P 22 - P 21) 21/2.

Ideally, P 22 = 2 P 21 = 4 P 1 . The absolute value of the power is to be selected so that when keying P 21 or (P 22 - P 21 ) / 2 with a fixed keying ratio T 2 = 0.5 (e.g. alternating 1 grid period on, 1 grid period off) or when keying P 1 with a variable pulse duty factor T 1, the permissible network effects (flicker) are not exceeded. A sensible design is carried out with P 1 = 1.5 kW, P 21 = 2.5 kW, P 22 = 4.5 kW.

The vibration package controller 7 is also assigned a setpoint generator 17 with which the size of the adjustable total electrical power of the circuit device can be predetermined. This can e.g. B. the setpoint of a temperature controller for the water heater.

It should also be mentioned that between the outer conductors L 1 and L 3 on the one hand and L 1 and L 2 on the other hand further branches analogous to branches 11 or 14 or 16 can additionally be connected in parallel.

For an explanation of the mode of operation of the circuit according to FIG. 5, reference is now made to the table. From this it can be seen that there are 7 performance areas. The performance ranges are such that, due to the keying of the electronic switches Tr 21 and Tr 22, rough tests result, which are superimposed on the switching states of the triac Tr 1 . A power between 0 and P 1 can be represented in the first power range. The electronic switches Tr 21 and Tr 22 are switched off.

Only the electronic switch Tr 1 is keyed by the vibration packet controller 7 in a pulse duty factor T 1 from 0 to 1. A power of 0 to 1.5 kW can be mastered almost continuously. If this performance is not sufficient, the system switches to performance area 2 . Here, the electronic switch Tr 22 is turned off while the electronic switch Tr 21 is keyed with a fixed duty cycle T 2 of 1/2. This results in a base load of P 21/2 of a variable finely adjustable power is superimposed according to the power range. 1 The maximum power results from the formula. A power from the power range 2 is shown in FIG. 7. The variable duty cycle that leads to power p 1 is indicated as the top curve 18 . The power p 21 is superimposed on this power. The power p 22 is 0. The resulting power p is shown in the right part of FIG. 7.

The time courses of the services each show average values of the service one or half a network period.

When the power is increased, the power can be increased anakogically over the power range 3 to the power range 4 , with FIG. 8 also explaining a specific power from the power range 4 here .

From this it can be seen that the electronic switchesTr 21st andTr 22 With a fixed duty cycleT 2nd of each¹/_2nd are groped and that there resulting services a variable service according to the service description rich1 fromp 1 is superimposed. The keying of the electronic switchesTr 21st  andTr 22 is from the vibration package control7 made so that each just one of the two resistorsR 21st respectively.R 22 is currently under tension. Ge is switched at zero current. Thus, compensate each other on the outer conductorL 1 andL 3rd, partly the network perturbations. The key of the circuitTr 1 is made so that there is always an opposite key to the resulting groping ofTr 21st andTr 22 is made, whereby the Network interference in the phase conductorL 1 partially compensate. The performancep 1  according toFig. 8 is different from performancep   inFig. 7 since the duty cycle towards theFig. 7 is varied. In the right part of theFig. 8 is the Total performance can be seen, which results from the superposition of the three parts stungenp 1,p 21st andp 22 as a total performancep results.  

The performance range 6 includes the illustration in FIG. 9, which also shows a specific performance from the performance range 6 . Stungsbereich In this Lei the electronic switch Tr is continuously switched 22, the electronic switch Tr 21 fixedly keyed with a fixed duty cycle T 2 _^1/2 and the electronic switch Tr1 scanned with a duty cycle variable from 0 to the first The keying of the power p 1 is chosen so that the cutoffs of this power are opposite the power p 21 . The network perturbations in the outer conductor L 1 compensate to the extent that an increase in power in the switching step of the power p 1 corresponds to a decrease in the power p 21 and vice versa. The same also applies to the switching states in power range 4 ; Here the power p 1 is sensed opposite to the larger switched power, based on the powers p 21 and p 22 . Since the power p 22 is the larger, p 1 is always switched in the opposite direction to p 22 . Thus, the repercussions in the outer conductor L 1 are also compensated here.

In the power range 7 , the electronic switches Tr 21 and Tr 22 are permanently conductive and the electronic switch Tr 1 can be varied according to power range 1 . The total power is obtained as the maximum value by continuously switching on the resistors R 1 , R 21 and R 22 .

The theoretically possible rough settings, in which p 22 is keyed with T 2 and p 21 is permanently switched on or off, are not provided due to the high network effects.

If one selects the powers P 1 , P 21 and P 22 such that P 1 is at least half as large as P 21 and that P 21 is half as large as P 22 , the result is a complete, fine-scale representation of the power in the range between 0 and the sum of P 1 + P 21 + P 22 .

In a concrete version, the power P 1 is selected to be 1.5 kW, the power P 21 to 2.5 kW and the power P 22 to 4.5 kW. The maximum power that can be represented between the outer conductors L 1 and L 3 is 7 kW. The finely adjustable total output varies between 0 and 8.5 kW.

While the circuit of Fig. 5 be an asymmetrical overall performance subjected to the three outer conductor results, the circuit of FIG. Complemented 6 to further resistors R 4 and R 0, which are parallel to each other as further branches 19 and 20 and between the outer conductors L 2 and L 3 are switched, the resistor R 4 being connected in series with a switch Tr 4 . In addition, there is another branch 21 in which a resistor R 3 with the associated switch Tr 3 is connected in series. This branch is connected in parallel to branch 16 and lies on the outer conductors L 1 and L 2 , so that new connection points 22, 23 and 24 result. The switches Tr 4 and Tr 3 can be triacs or mechanical switches. The branches 19, 20 and 21 serve on the one hand to increase the total power and on the other hand to the symmetrical loading of the outer conductor when all branches are switched on.

According to the illustration, the resistor R 0 is always connected to the voltage of the outer conductors L 2 and L 3 , in practice it is controlled or switched on by a so-called water switch in the instantaneous water heater, the water switch then giving a switch-on command when water flow through the channel 6 he follows.

Other areas of application of the circuit would be e.g. B. cookers or heating Fan.

Claims (13)

1. Circuit for carrying out the method according to the main claim of the patent (DE part of the PCT application PCT DE 85 00 474) for supplying an electrical load, in particular a continuous-flow heater, which is fed by a three-phase voltage source and has resistances which are at least between two outer conductors of the voltage source, characterized in that between the conductors (L 1 , L 3 ) of a first outer conductor pair two resistors (R 21 , R 22 ) resulting in unequal powers when switched on continuously and in series with an electronic switch (Tr 21, Tr 22) are arranged, said switches being perio operated disch oscillation packet is controlled and the duty ratio (oN time based on the period duration) _^1/2, and currently only one resistance to voltage, and in that between the Lei tern (L 1, L 3 ) another pair of outer conductors, another resistor (R 1 ) in series with another electronic switch he (Tr 1 ) is net, which is operated periodically vibration package controlled with variable duty cycle. 2. Circuit according to claim 1, characterized in that with a scarf ter (Tr 3 , Tr 4 ) serial fixed value resistors (R 3 , R 4 ) in the second and resulting third outer conductor pair are arranged so that all resistors are switched on continuously a symmetrical power distribution to all three outer conductors (L 1 , L 2 , L 3 ) results. 3. A circuit according to claim 1, characterized in that the resistors (R 1 , R 21 and R 22 ) are dimensioned so that when a certain voltage is applied, the powers behave such that P 1 < P 2 < P 22 , P 1 is the power at the resistor (R 1 ), etc. 4. A circuit according to claim 3, characterized in that the resistors (R 1, R 21 and R 22) are dimensioned such that the drop across them upon application of a certain voltage power P 1 ≦ P 21/2 and P 1 ≦ ( P 22 - P 21 ) / 2, if P 22 <2 P 21 , where P 1 is the power output in the resistor (R 1 ), etc. 5. A circuit according to claim 3, characterized in that the resistors (R 1 , R 21 and R 22 ) are dimensioned such that the power falling on them when a certain voltage is applied to power P 21 ∼ P 22/2 and P 1 ∼ P 21/2 , where P 1 is the power output in the resistor (R 1 ), etc. 6. Procedure for fine adjustment of the power of a resistor, that of two connected to a supply voltage source via switches there are unequal resistances, especially according to claim 1, because characterized in that the greater partial resistance with a perio Vibration control with a fixed duty cycle and the smaller part resistance with a periodic vibration package control variable duty cycle is controlled. 7. The method according to claim 6, characterized in that the larger counter stood twice the size of the smaller one. 8. The method according to claim 6, characterized in that the fixed Tastver ratio is 0.5. 9. The method according to claims 6 or 8, characterized in that the one switching period of the fixed duty cycle is one network period. 10. The method according to claim 6, characterized in that the switch-on time points of the smaller resistance identical to the switch-off times of the are larger and the switch-off times of the smaller are identical to the Switch-on times of the larger are. 11. The method according to claim 6, characterized in that the resistors a single-phase AC voltage.   12. The method according to claim 6, characterized in that the resistors are on different outer conductors of a three-phase system. 13. Procedure for adjusting the power on a resistor by perio Vibration package control with different duty cycles, in particular according to claim 1, characterized in that the switch-on duration or switch-off duration in a maximum possible number of individual times sections of one or more network periods is divided and between these periods for one or more network periods switches or is switched on.