CN201750185U - Negative pressure-driven flow continuing device - Google Patents
Negative pressure-driven flow continuing device Download PDFInfo
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- CN201750185U CN201750185U CN2010202863313U CN201020286331U CN201750185U CN 201750185 U CN201750185 U CN 201750185U CN 2010202863313 U CN2010202863313 U CN 2010202863313U CN 201020286331 U CN201020286331 U CN 201020286331U CN 201750185 U CN201750185 U CN 201750185U
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- negative pressure
- negative
- out terminal
- mosfet
- leading
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Abstract
The utility model relates to a negative pressure-driven flow continuing device, belonging to technical field of the control of a DC (direct current) power supply. The device comprises a positive leading-out terminal, a negative leading-out terminal, a negative pressure identifying diode, an energy storing capacitor, a voltage detecting chip, two MOSFET (metal oxide semiconductor field effect transistor) electronic switch devices and a buffering capacitor. The negative leading-out terminal is connected with a power supply end of the voltage detecting chip by the reversed negative pressure identifying diode and is connected with one end of the energy storing capacitor; the other end of the energy storing capacitor is connected with the ground end of the voltage detecting chip; the drain electrodes of the two MOSFET electronic switch devices are respectively connected with the positive leading-out terminal and the negative leading-out terminal; the source electrodes of the two MOSFET electronic switch devices are connected with each other and are connected with the ground pin of the voltage detecting chip; the grid electrodes of the two MOSFET electronic switch devices are connected with each other and are connected with the output end of the voltage detecting chip; and the buffering capacitor is connected between the positive leading-out terminal and the negative leading-out terminal in parallel. Compared with the prior art, the device not only can timely continue the flow to supply the power when the battery in a battery pack is broken, but also has simple circuit and small part, thereby being economic in cost, small in power consumption during flow continuing, and good for popularization and application.
Description
Technical field
The utility model relates to a kind of follow current control device, and especially a kind of negative pressure drive current following device belongs to DC power supply control technology field.
Background technology
Understand according to the applicant, in big-power solar photovoltaic series connected battery group power-supply system, if indivedual solar photovoltaic cell panel breaks down (be blocked, vibrate as ambient temperature, illumination part, get loose etc.), to become resistive device, and cause two-port negative pressure to occur.As a result, not only solar power supply system cisco unity malfunction, and the cell panel that breaks down can produce hot spot and damage and cause great economic loss.This phenomenon is not rarely seen, happens occasionally in big-power solar photovoltaic plant application system.
96197701.9,86101403,02800874.X, 98120609.2,97120561.2,00135965.7,200720027837.0,200610096986.2, Chinese patent application such as 200720041754.7 disclosed the progress of relevant DC power supply (containing wind energy power supply, solar photovoltaic power) control device aspect in recent years respectively existing Chinese patent retrieval is found that application number is:.But above-mentioned DC power supply control device majority is used for civil power (alternating current) conversion direct current, and is not to directly apply to the DC power supply that battery pack constitutes.Though relate to individually direct current afterflow principles, cost diseconomy not only, and can not effectively solve the battery power system and be the problem that the negative voltage malfunction causes because of individual cell generation borderline failure.
Further retrieval is found, application number is that 200720093866.7 Chinese patent discloses a kind of batteries current following device, and purpose is to allow the batteries power supply really reach uninterrupted.This device mainly is made up of diode, two contact chips, spring, and two contact chips connect battery positive voltage and negative pole respectively.When battery had fault impedance to uprise, diode became forward bias by reverse bias, and conducting reaches the purpose of afterflow, if electric current is very big, when diode generation change or deformation, contact chip is closely contact under the effect of spring, and this battery of short circuit still reaches the purpose of afterflow.When using diode continuousing flow, two ends can produce and be generally the 0.75V tube voltage drop but to the in-depth analysis of actual use as can be known; When battery current reaches 10A, 20A, tube voltage drop even can arrive 1V~1.5V greatly.Therefore, the power that diode consumed will reach 10W~20W or bigger, and not only diode self high temperature heating damages easily, even can damage adjacent storage battery, has safety issue and unreliable hidden danger; Even rely on contact chip short circuit afterflow under spring action, also reliable inadequately, reason one is that diode burns out under the big function of current very soon, makes contact chip have little time closed short circuit at all; The 2nd, the temperature control short circuit spacing of contact chip can't accurately be measured setting, the 3rd, even contact chip forms short circuit, treat that temperature descends after, form again and open circuit, can't continue afterflow.
For this reason, the applicant's number of filing an application once is 200910035051.7, name is called the Chinese patent application of " self-excitation driving follow current control device ".Though the technical scheme that this application proposes can solve the problem that prior art exists, the circuit structure more complicated, cost is economical inadequately.
The utility model content
The purpose of this utility model is: propose a kind ofly not only can guarantee when individual cell breaks down in battery pack in time to recover battery-powered, and negative pressure drive current following device simple in structure, cost economy, lose the use coil part, thereby make it can obtain practical applying.
In order to reach above purpose, negative pressure drive current following device of the present utility model contains the positive and negative exit that is connected to positive source and negative pole respectively, and negative pressure identification diode, energy storage capacitor, voltage checking chip, two MOSFET electronic switching devices, buffer capacitor; Described negative exit connects the power end of voltage checking chip through reverse negative pressure identification diode, and connects an end of energy storage capacitor; The ground end of the described voltage checking chip of another termination of described energy storage capacitor; The drain electrode of described two MOSFET electronic switching devices connects described positive and negative exit respectively; The source electrode of described two MOSFET electronic switching devices links to each other, and connects the lower margin of described voltage checking chip; The grid of described two metal-oxide-semiconductor electronic switching devices links to each other, and connects the output of described voltage checking chip; Described buffer capacitor is connected in parallel between the described positive and negative exit.
During work, under the normal condition, negative pressure identification diode is obstructed.When appearance is unusual, the voltage reversal on the positive and negative exit, negative pressure identification diode current flow charges rapidly to energy storage capacitor.Valve point on charging voltage value arrival voltage checking chip, its output will be exported high level, thereby make the electronic switch short circuit, constitute the afterflow bypass, and power-supply system still can operate as normal.
Be not difficult to find out, the utility model compared with prior art, afterflow in time power supply when not only the battery in battery pack breaks down, and circuit is simple and direct, device is few, so cost economy.And since discharge time of this circuit much larger than the charging interval, so the power consumption of afterflow working hour is very little, thereby more helps applying.
Description of drawings
Below in conjunction with accompanying drawing the utility model is further described.
Fig. 1 is the circuit theory diagrams of an embodiment of the utility model.
Embodiment
Embodiment one
The negative pressure drive current following device of present embodiment mainly is made of negative pressure identification diode D1, energy storage capacitor C1, voltage checking chip IC1, N-channel MOS FET pipe electronic switch VM1 and VM2, buffer capacitor C2 as shown in Figure 1.Its "+", "-" exit are connected to positive source and negative pole respectively."-" exit connects each power end (1 of voltage checking chip IC1 through reverse negative pressure identification diode D1,2,3,8 pin), and to the end of energy storage capacitor C1, another termination of this energy storage capacitor C1 is as voltage checking chip (adopt the IR2101 chip for driving, include the output of voltage detecting and high level).The ground end of IC1 (4,6 pin).The drain D 1 of two N-channel MOS FET pipes, D2 connect "+", "-" exit respectively; Its source S 1, S2 link to each other, and connect the lower margin of voltage checking chip; Its grid G 1, G2 link to each other, and connect the output (7 pin) of voltage checking chip.Buffer capacitor C2 is connected in parallel between "+", "-" exit.
During work, under the normal condition, the voltage on the exit is forward, and D1 is obstructed for negative pressure identification diode, and the voltage that is present in the energy storage capacitor C1 between the V point and B point among the figure can be released gradually.If the voltage of energy storage capacitor C1 is lower than the lower valve point (about 8V) of voltage detecting core IC1, the output of IC1 (7 pin) is output low level, thereby the MOSFET pipe as electronic switch is ended., the power-supply system operate as normal.
When appearance is unusual, be connected in parallel on "+", solar photovoltaic cell panel between "-" exit breaks down and (is blocked, vibrates as ambient temperature, illumination part, get loose etc.) become resistive, so appear at the voltage reversal on "+", "-" exit, negative pressure identification diode D1 conducting, the malleation on "-" exit is by negative pressure identification diode D1, and C1 charges rapidly to energy storage capacitor.Go up valve point (about 9V) when magnitude of voltage arrives voltage checking chip IC1, its output (7 pin) will be exported high level (being energy storage capacitor C1 voltage), thereby make the electronic switch short circuit, and power-supply system still can operate as normal under bypass afterflow working condition.
In the afterflow course of work, no longer conducting of negative pressure identification diode D1, the voltage of energy storage capacitor C1 is by voltage checking chip IC1 and electronic switch grid source conductive discharge ...., thereby return initial condition.Because above process, discharge time is much larger than the charging interval, and therefore in afterflow working hour, switch short circuit pressure drop is exactly the MOSFET conduction voltage drop, and power consumption is very little.
In addition to the implementation, the utility model can also have other execution mode.For example, voltage checking chip IC1 and MOSFET electronic switching device also can select for use other chip with similar functions or device to replace, and these all constitute the replacement that is equal to of the present utility model.
Claims (3)
1. negative pressure drive current following device is characterized in that: contain the positive and negative exit that is connected to positive source and negative pole respectively, and negative pressure identification diode, energy storage capacitor, voltage checking chip, two MOSFET electronic switching devices, buffer capacitor; Described negative exit connects the power end of voltage checking chip through reverse negative pressure identification diode, and connects an end of energy storage capacitor; The ground end of the described voltage checking chip of another termination of described energy storage capacitor; The drain electrode of described two MOSFET electronic switching devices connects described positive and negative exit respectively; The source electrode of described two MOSFET electronic switching devices links to each other, and connects the lower margin of described voltage checking chip; The grid of described two metal-oxide-semiconductor electronic switching devices links to each other, and connects the output of described voltage checking chip; Described buffer capacitor is connected in parallel between the described positive and negative exit.
2. negative pressure drive current following device according to claim 1 is characterized in that: described MOSFET electronic switching device is N-channel MOS FET pipe.
3. negative pressure drive current following device according to claim 2 is characterized in that: described voltage checking chip adopts the IR2101 chip for driving that includes voltage detecting and high level output.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN2010202863313U CN201750185U (en) | 2010-08-10 | 2010-08-10 | Negative pressure-driven flow continuing device |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN2010202863313U CN201750185U (en) | 2010-08-10 | 2010-08-10 | Negative pressure-driven flow continuing device |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CN201750185U true CN201750185U (en) | 2011-02-16 |
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Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN2010202863313U Expired - Lifetime CN201750185U (en) | 2010-08-10 | 2010-08-10 | Negative pressure-driven flow continuing device |
Country Status (1)
| Country | Link |
|---|---|
| CN (1) | CN201750185U (en) |
Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN101931251A (en) * | 2010-08-10 | 2010-12-29 | 江苏尚特风光电力工程有限公司 | Negative pressure drive current following device |
-
2010
- 2010-08-10 CN CN2010202863313U patent/CN201750185U/en not_active Expired - Lifetime
Cited By (2)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN101931251A (en) * | 2010-08-10 | 2010-12-29 | 江苏尚特风光电力工程有限公司 | Negative pressure drive current following device |
| CN101931251B (en) * | 2010-08-10 | 2013-04-17 | 江苏尚特风光电力工程有限公司 | Negative pressure drive current following device |
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Legal Events
| Date | Code | Title | Description |
|---|---|---|---|
| C14 | Grant of patent or utility model | ||
| GR01 | Patent grant | ||
| AV01 | Patent right actively abandoned |
Granted publication date: 20110216 Effective date of abandoning: 20130417 |
|
| RGAV | Abandon patent right to avoid regrant |