CN210429529U - Coreless transformer based on secondary side parallel fractional order circuit - Google Patents

Abstract

The utility model discloses a coreless transformer based on a secondary side parallel fractional order circuit, which comprises a primary side loop and a secondary side loop; the primary side loop comprises a primary side fractional order capacitor with the order larger than 1 and a primary side coil with internal resistance, and the primary side fractional order capacitor and the primary side coil are connected in series; the secondary side loop comprises a secondary side coil with internal resistance, a secondary side fractional order capacitor and a load, and the secondary side coil, the secondary side fractional order capacitor and the load are connected in parallel; and a transformer core is not arranged between the primary side coil and the secondary side coil. The utility model discloses utilize the order to be greater than 1 once side fractional order electric capacity and provide the energy for transformer load, simultaneously when the order is fixed the operating frequency and the appearance value of once side fractional order electric capacity can follow no iron core transformer parameter variation automatically to realize that no iron core transformer can both keep high efficiency work under the load of different power factors, solved traditional transformer heavy, problem with high costs.

Description

Coreless transformer based on secondary side parallel fractional order circuit

Technical Field

The utility model belongs to the technical field of the technique of transformer and specifically relates to indicate a no iron core transformer based on parallel type fractional order circuit of secondary side.

Background

In 1831, faraday utility model, called "faraday induction coil", was the first elementary transformer in the world, in 1885, the west house company engineers william stanza made the first practical transformer, after which the transformer began to be an extremely versatile power device, mainly used for power transmission, voltage conversion and insulation. The conventional transformer is a device for changing an ac voltage based on the principle of electromagnetic induction, and mainly includes a primary coil, a secondary coil, and an iron core (magnetic core), where the primary coil and the secondary coil are coupled via the iron core. The iron core has the function of strengthening the magnetic coupling between the two coils, so that the transformer realizes efficient power transmission. However, the conventional transformer has high cost and heavy weight due to the existence of the iron core. In order to remove the iron core of the transformer, numerous scholars at home and abroad begin to research the construction technology of the iron-core-free transformer, however, most of the existing iron-core-free transformers only realize high-efficiency electric energy transmission by simply increasing the frequency or can only work efficiently under resistive load.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to overcome prior art's shortcoming and not enough, provide a no iron core transformer based on the parallelly connected type fractional order circuit of secondary side, utilize fractional order circuit to realize a transformer that need not the iron core, can replace the transformer that the tradition has the iron core, make transformer reduce cost and weight become for probably. The primary side fractional order capacitor with the order greater than 1 is used for providing energy for a transformer load, and meanwhile, when the order is fixed, the working frequency and the capacitance value of the primary side fractional order capacitor can automatically follow the parameter change of the coreless transformer, so that the coreless transformer can keep high-efficiency work under loads with different power factors, and the problems of large weight and high cost of the traditional transformer are solved.

In order to achieve the above object, the present invention provides a technical solution: a coreless transformer based on a secondary side parallel fractional order circuit comprises a primary side loop and a secondary side loop; the primary side loop comprises a primary side fractional order capacitor with the order greater than 1 and a primary side coil with internal resistance, and the primary side fractional order capacitor and the primary side coil are connected in series; the secondary side loop comprises a secondary side coil with internal resistance, a secondary side fractional order capacitor and a load, and the secondary side coil, the secondary side fractional order capacitor and the load are connected in parallel; a transformer core is not arranged between the primary side coil and the secondary side coil; the primary side fractional order capacitor with the order greater than 1 has the property of negative resistance, can provide energy for a load of a transformer, and has two working modes: firstly, the order of the capacitor is constant, and the working frequency and the capacitance value automatically change along with the parameters of the coreless transformer so as to keep the capacitor to work stably; secondly, the working frequency is fixed, and the order and the capacitance value automatically follow the parameter change of the coreless transformer so as to keep the capacitor to work stably.

Further, the differential relation between the voltage and the current of the primary-side fractional order capacitor and the secondary-side fractional order capacitor satisfies:

the phase relation satisfies

Wherein i_CIs a fractional order of the capacitor current, v_CIs the fractional order of the capacitor voltage, α is the fractional order of the capacitor, C_αIs the fractional order capacitance value, and the order of the first-side fractional order capacitance is 1 < α₁< 2, the order of the secondary side fractional order capacitor is 0 < α₂≤2。

Further, the capacitance value and the order of the secondary side fractional order capacitor are fixed.

Compared with the prior art, the utility model, have following advantage and beneficial effect:

1. the utility model discloses a transformer need not the iron core, simple structure.

2. Compared with the traditional transformer, the weight is greatly reduced.

3. Under different power factor loads, the transformer can still keep high-efficiency operation.

Drawings

Fig. 1 is a model diagram of the coreless transformer of the present invention in an embodiment.

Fig. 2 is a graph of efficiency versus load for a coreless transformer in an embodiment.

Fig. 3 is a graph of output power versus load for a coreless transformer in an embodiment.

Detailed Description

To further illustrate the aspects and features of the present invention, the following detailed description of the embodiments of the present invention is provided in conjunction with the accompanying drawings, but the invention is not limited thereto.

As shown in fig. 1, the coreless transformer based on the secondary side parallel fractional order circuit provided in the present embodiment includes a primary side loop and a secondary side loop; the primary side loop comprises a primary side fractional order capacitor C with the order greater than 1_α1And with an internal resistance R₁Primary side coil L of₁The primary side fractional order capacitance C_α1And a primary side coil L₁Are connected in series; the secondary side loop comprises a secondary side loop with an internal resistance R₂Secondary side coil L of₂A fractional order capacitor C_α2And a load R_LThe secondary side coil L₂A fractional order capacitor C_α2And a load R_LAre connected in parallel; the primary side coil L₁And a secondary side coil L₂And no transformer core is arranged between the two. Wherein, the order is greater than the first side fractional order capacitance C of 1_α1Having the property of negative resistance, being the load R of the transformer_LProviding energy.

In this embodiment, the order of the primary side fractional order capacitor C is greater than 1_α1The device has the characteristic of constant apparent power and has two working modes: firstly, the order of a capacitor is constant, and the working frequency and the capacitance value automatically change along with the parameters of the coreless transformer; secondly, the working frequency is fixed, and the order and the capacitance value automatically follow the parameter change of the coreless transformer.

According to the coupled mode theory, the coupled mode equation of the coreless transformer shown in fig. 1 is:

in the formula, g₁、τ₂The gain of the primary side loop and the loss of the secondary side loop, and g₁＝-(τ_Ca1+τ_L1)，τ₂＝τ_Ca2+τ_L2+τ_RLIn which τ is_Ca1、τ_L1、τ_Ca2、τ_L2、τ_RLThe loss rates of the elements of the coreless transformer are respectively,

where k is the mutual inductance coupling coefficient, ω, of the primary and secondary side coils₁,ω₂The resonant angular frequencies of the primary side loop and the secondary side loop respectively are expressed as follows:

the specific expression of the loss rate of each element is as follows:

the condition that the iron core-free transformer has the steady state solution can be obtained by the formula (1) as follows:

further, it is obtained from the formulae (1) and (9):

the efficiency of the available coreless transformer is generally expressed as:

the output power of the coreless transformer is generally expressed as follows:

wherein:

in the formula, V_Ca1Is the effective value of the fractional order capacitor voltage.

From equation (1), the operating frequency of the coreless transformer is solved as follows:

when the primary-side fractional order capacitor works in the fixed order mode, let α₁＝α₀Is constant, therefore, the load resistance loss coefficient of the coreless transformer obtained by the above formula when the order of the primary side fractional order capacitor is fixed needs to satisfy:

τ_{RL_C}is the critical operating point of a coreless transformer. When tau is_RL＞＝τ_{RL_C}When the primary side fractional order capacitor cannot work in the order fixing mode, otherwise, the primary side fractional order capacitor cannot stably work without working frequency solution, so that the primary side fractional order capacitor is automatically switched to the working frequency fixing mode, namely omega is equal to omega₂。

When the primary-side fractional order capacitor operates in a fixed order mode, it can be obtained from equations (10) - (14)

The transmission efficiency is:

the output power is approximately:

wherein S is_Ca1Is the apparent power, Q, of the primary-side fractional order capacitor_LTIs the quality factor of the primary side loop. Therefore, according to the formula, the transmission efficiency and the output power of the coreless transformer are independent of the mutual inductance and the secondary side resonance frequency, namely, the transmission efficiency and the output power of the coreless transformer are not influenced by the power factor of the load. When the primary-side fractional order capacitor works in the fixed working frequency mode, the transmission efficiency and the output power of the coreless transformer obtained by the equations (9) - (14) are respectively:

the parameters of the transformer without the iron core are set as follows: l is₁＝L₂20 muH, secondary side fractional order capacitance order α₂1, the coupling coefficient k is 0.25, and the secondary side rated resonant frequency is ω₂₀2 pi x 100kHz, internal resistance R₁＝R₂0.1. one-time side fractional order capacitance order of α₀＝1.1，S_Cα1The critical load is R when 500 is obtained_L30 Ω. Therefore, the relationship curves of the transmission efficiency, the output power and the load of the coreless transformer can be obtained as shown in fig. 2 and fig. 3, respectively. As can be seen from FIGS. 2 and 3, when R is_LAnd when the output power is more than or equal to 30 omega, the transmission efficiency and the output power of the coreless transformer are constant.

According to the above analysis, the utility model discloses a no iron core transformer based on parallelly connected type fractional order circuit of secondary side, in the load scope of design, no matter be the change of load or secondary side resonant frequency's skew, no iron core transformer can all realize the invariable efficient transmission of efficiency and output, and this and traditional no iron core transformer exist than difference, the utility model discloses no iron core transformer's advantage is obvious, is worth promoting.

The above embodiments are preferred embodiments of the present invention, but the embodiments of the present invention are not limited by the above embodiments, and any other changes, modifications, substitutions, combinations, and simplifications which do not depart from the spirit and principle of the present invention should be equivalent replacement modes, and all are included in the scope of the present invention.

Claims (3)

1. A no iron core transformer based on secondary side parallel fractional order circuit which characterized in that: comprises a primary side loop and a secondary side loop; the primary side loop comprises a primary side fractional order capacitor (C) with order greater than 1_α1) And with internal resistance (R)₁) Primary side coil (L)₁) The primary side fractional order capacitance (C)_α1) And a primary side coil (L)₁) Are connected in series; the secondary side loop comprises a secondary side loop with an internal resistance (R)₂) Secondary side coil (L)₂) Secondary side fractional order capacitor (C)_α2) And a load (R)_L) SaidSecondary side coil (L)₂) Secondary side fractional order capacitor (C)_α2) And a load (R)_L) Are connected in parallel; the primary side coil (L)₁) And a secondary side coil (L)₂) The transformer iron core is not arranged between the two parts; wherein the order is greater than 1, and the primary side fractional order capacitor (C)_α1) Having the property of negative resistance, can be the load (R) of a transformer_L) Provides energy and has two modes of operation: firstly, the order of the capacitor is constant, and the working frequency and the capacitance value automatically change along with the parameters of the coreless transformer so as to keep the capacitor to work stably; secondly, the working frequency is fixed, and the order and the capacitance value automatically follow the parameter change of the coreless transformer so as to keep the capacitor to work stably.

2. The coreless transformer of claim 1, wherein the coreless transformer is based on a secondary side parallel fractional order circuit, and is characterized in that: the primary side fractional order capacitance (C)_α1) And a secondary side fractional order capacitor (C)_α2) The voltage and current differential relation satisfies:

the phase relation satisfies

Wherein i_CIs a fractional order of the capacitor current, v_CIs the fractional order of the capacitor voltage, α is the fractional order of the capacitor, C_αIs a fractional order capacitance value, and a primary side fractional order capacitance (C)_α1) Order 1 < α₁< 2, secondary side fractional order capacitance (C)_α2) Order 0 < α₂≤2。

3. The coreless transformer of claim 1, wherein the coreless transformer is based on a secondary side parallel fractional order circuit, and is characterized in that: the secondary side fractional order capacitance (C)_α2) Is fixed.

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