• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The invention comprises a regulating device (2) for a viscoclutch (4) which is provided with a primary disc (6) and a secondary disc (8), the primary disc having a first rotation speed (10) and the secondary disc a second rotation speed (12), which regulating device (2) is adapted to receiving signals which represent said rotation speeds and a desired degree of engagement (14), and to calculating a prevailing degree of engagement (15) between the primary disc and the secondary disc as the ratio between said second and first rotation speeds (12, 10). The degree of engagement between the discs is controlled by the regulating device on the basis of a desired degree of engagement (14) by regulating an amount of viscous oil between them by delivering a control signal (16) to an oil pump unit (18) which is adapted to pumping oil (20) into the viscoclutch (4) in response to the control signal. If the desired degree of engagement (14) is higher than an adjustable upper level (22) the regulating device is adapted to regulating the engagement of the viscoclutch according to a first regulating strategy which involves alternately changing the control signal (16) by first generating a control signal to the oil pump unit for maximum engagement and thereafter, when the degree of engagement has been substantially constant for longer than a predetermined first amount of time (Atl), changing the control signal to effect a degree of engagement below said upper level (22) until the degree of engagement is no longer substantially constant.
    公开号:SE1151225A1
    申请号:SE1151225
    申请日:2011-12-20
    公开日:2013-06-21
    发明作者:Svante Johansson;Alexander Drexel
    申请人:Scania Cv Ab;
    IPC主号:
    专利说明:

    Between the times that the valve is in these respective positions. For example, a time period may be 0.25 seconds, i.e. the valve is controlled in the case with the frequency 4 Hz where regulation can take place by specifying how much of the time period the valve should be open. If the valve is open during the entire time period, the fl fate is maximum (l00%) and if the valve is closed during the entire time period, the fl fate is minimal (0%). The valve can be adjusted so that all positions between 0-100% can be taken.
    When the valve is open, oil is pumped into the working chamber of the viscous coupling and the degree of connection is thereby controlled. The viscous coupling comprises a number of circular lamellae on the primary and secondary disks between which the oil is found. The oil is pressed outwards in the viscous coupling by the centrifugal force and is then caused to fl inwardly to a collecting chamber by a pumping action which takes place, for example, with a specially designed lamella which is arranged near the outer edge of one of the disks. This pumping effect is thus lower the higher the degree of connection that the viscous connection has, ie. it takes longer to empty the viscous coupling on oil if the coupling rate is high.
    When disconnecting, the viscous connection will always have a minimum degree of connection of e.g. 20% (at minimum oil supply / oil quantity), and a maximum fill connection of approx. 90% relative to the primary disk (at maximum oil supply / oil quantity). Within these limits, the end positions of the viscous coupling have an individual variation that depends on the spread in manufacturing tolerances and / or aging / wear, ie. the possible range of controls is not known.
    The viscous coupling also has the ability, when regulated close to full engagement, to "jump up" and get stuck in full engagement. When the viscous clutch is stuck in fi ill engagement, or trying to be adjusted to areas outside its end positions, this causes a problem with integrator twisting. For an adjustable coolant pump, for example, the control is extra sensitive to this because it has a narrow control range in comparison with, for example, a viscous coupling for a fl genuine that works with higher torques and which has a wider control range and thereby provides the opportunity for more aggressive control. As a result of this, when using a viscous connection in connection with a coolant pump, long response times are obtained, which directly affects fuel consumption during disconnection and cooling performance when switching on the pump.
    Control systems for viscous couplings are previously known, for example by the following patent document_ US-2003 / 0l33242 relates to a control system for controlling a fl genuine adapted for cooling an internal combustion engine where the fl genuine is driven via a viscous coupling. The degree of engagement of the viscous coupling is limited so that it is not allowed to exceed an upper limit, thereby reducing the disengagement times of the viscous coupling. US-2008/0185254 also relates to a control system for controlling a viscous coupling for a genuine. The control is done, among other things, by calculating the difference between the desired fl speed and measured fl speed and comparing this difference with different speed conditions for kten the speed.
    Finally, US-2003 / 0l23 995 discloses a viscous coupling connected to a coolant pump for cooling an engine. The degree of engagement of the viscous coupling can be changed, among other things, by changing the size of a chamber in the viscous coupling for the viscous oil.
    The object of the present invention is to provide a control of a viscous coupling which shortens the times for disconnection of the viscous coupling at engagement degrees which are close to the maximum engagement degree, and also reduces the risk of so-called integrator twisting. A further object is to improve the control of a viscous coupling at engagement degrees which are close to the minimum degree of engagement. A general object of the present invention is to provide an improved control of a viscous coupling.
    Summary of the Invention The above objects are achieved by the invention defined by the independent claims. Preferred embodiments are defined by the dependent claims.
    According to an embodiment of the invention it is achieved that when the desired connection degree is higher than a predetermined high level, a control signal is given to the pump to pump with maximum fl fate, and as soon as the measured connection degree, at maximum fl fate, has been substantially constant for a predetermined time. the engagement rate is no longer constant, and when the viscous engagement begins to drop, ie. the degree of connection decreases, a control signal is again given regarding the maximum fl fate.
    To solve the control problems, the present invention comprises a set of control strategies where the control span, i.e. the degree of engagement of the viscous coupling, is divided into three control areas. 1. Upper prohibited area 2. A permitted area 3. A lower prohibited area The permitted area is limited upwards by an upper level and downwards by a lower level. Upper prohibited regulator council: When the regulator device receives a request, ie. a desired degree of connection, within what is considered to be the upper prohibited area, within which the viscous connection cannot be regulated without risking so-called integrator twisting, the control device transitions to a first control strategy. If the viscous coupling is given a full control signal, the pump will be fully engaged, which results in the viscous coupling being filled with excess oil. This results in an unnecessarily long disconnection time, as discussed above. When the maximum connection of the viscous coupling is not known, or which control signal engages the viscous coupling exactly fully, the degree of engagement of the viscous coupling is monitored. This can be done by determining the ratio between the rotational speeds of the secondary disk and the primary disk, and when that ratio (the degree of engagement) has been constant for a predetermined period of time, the degree of engagement is considered to have stabilized. This is achieved by first giving the pump a full control signal to quickly reach full engagement. When the degree of engagement of the viscous coupling has then stabilized, the oil supply is throttled, for example to the last control signal within the permitted control range. When the engagement degree then indicates that the viscous coupling is about to be disengaged again, the control signal is controlled again until the engagement degree is stabilized again in full engagement. In this way, the chamber is not filled with excess oil and thus a faster response time for disconnection is obtained. To disengage the viscous clutch, first throttle all oil supply until the viscous clutch is disengaged before the regulator device begins to regulate.
    According to the invention, the oil level in the viscous coupling is thus regulated so that it is just enough to achieve the desired high coupling level.
    Lower forbidden control range: When the controller device receives a request for a desired degree of connection within what is considered to be the lower forbidden range (below the viscous end position), to which the viscous coupling can not be adjusted without risk of integrator twisting, the controller device switches to full disconnection logic by applying a second regulatory strategy.
    The possible disconnection degree of the viscous connection (minimum engagement degree) varies, however, as it depends on, for example, the working temperature of the viscous oil and the primary disk speed, as well as manufacturing tolerances and aging. Therefore, according to the method of the invention, the lower level which constitutes the limit of the lower prohibited control council is continuously updated.
    The lower level is adjusted so that it receives an offset above the minimum engagement level.
    The smallest possible degree of connection is detected and with an offset this is set to the limit of the forbidden lower area. When a request for a desired degree of connection is located in this region, the pump is controlled to full disconnection. If the pump does not reach back to the previous disconnection degree, the connection degree is monitored. When this has stabilized, which indicates that the pump cannot disconnect further, the limit for the forbidden lower region is increased up to the current level.
    According to a further aspect of the present invention, the following control can be performed with a normal control strategy within the allowable control range: If the pump should get stuck in full engagement when the request is within the allowable control range, the integral part of the control is monitored. If the degree of engagement of the viscous coupling is detected within the upper prohibited range, there is a great risk that the viscous coupling is stuck. This saves the current integral part. If the integrator is then turned over a maximum limit, the regulator is switched off and all oil supply is throttled to release the viscous clutch from full clutch. When the viscous coupling is detected again within the controllable area, controller control continues, now with a faster response thanks to reduced integrator torque. If the pump is regulated back before the maximum limit for integrator torque is reached, the logic of the PID controller in this respect is reset.
    The present invention has, among other things, the following advantages: The strategy of first throttling all oil supply to release the viscous clutch from full engagement saves, for a specific realization, about 60 seconds in response time, plus that integrator twisting is avoided. When regulating with the first control strategy, ie. to monitor and control the switch-on degree so that it is substantially constant, in fi ill switch-on, the switch-off time is shortened by a further approximately 10 seconds. This results in, among other things, better fuel economy.
    By using special control strategies (the first and second control strategies) to turn off the control with the normal control strategy in the upper and lower forbidden control areas, as well as integrator monitoring, gives a control response time that can be about 60 seconds faster (if the controller is affected by integrator distortion). The faster response time can be crucial to ensure good cooling performance, but above all enables increased fuel savings.
    Brief Description of the Drawings Figure 1 is a schematic block diagram illustrating the present invention.
    Figure 2 shows graphs intended to illustrate the present invention.
    Figures 3-5 show simplified fate diagrams intended to illustrate various embodiments of the present invention. Detailed Description of Preferred Embodiments of the Invention Referring to the block diagram of Figure 1, the invention will now be described in more detail. This is also done by reference to the graphs shown in Figure 2 where the top graph shows a desired degree of engagement 14 percent with respect to time t, the middle graph shows the control signal 16 percent with respect to the oil pump unit 18 with respect to time t, and the lowest the graph shows the current, measured, engagement rate 15 in percent for the viscous engagement with respect to time t.
    The invention thus relates to a control device 2 for a viscous coupling 4 of a conventional type which comprises a primary disk 6 and a secondary disk 8.
    During operation, the primary disk has a first rotational speed 10 and the secondary disk has a second rotational speed 12 and control device 2 is adapted to receive signals regarding the rotational speeds and regarding a desired degree of engagement 14.
    The control device is adapted to calculate a current degree of connection 15 between the primary disk and the secondary disk as the ratio between the second 12 and the first 10 rotational speed. The degree of engagement between the disks is controlled by the control device depending on a desired degree of engagement 14. This is accomplished by controlling the amount of viscous oil between the disks by delivering a control signal 16 to an oil pump unit 18 adapted to pump oil 20 into the viscous coupling depending on the control signal.
    If the desired degree of engagement 14 is higher than an adjustable upper level 22, the control device is adapted to control the engagement of the viscous coupling according to a first control strategy. This occurs when the control device 2 receives a signal 14 indicating that the viscous clutch is to be switched on according to a desired switching degree 14 which is shown in the top graph in Figure 2 at the time t1 where the desired switching degree is higher than level 22. This first control strategy involves alternately changing the control signal. 16 by first generating a control signal to the oil pump unit for maximum connection. This takes place during the interval tl - a, where the control signal is displayed in the middle graph and the measured engagement rate appears in the bottom graph. Then, when the degree of engagement has been substantially constant for longer than a predetermined first time period (Atl), the control signal changes to produce a degree of engagement lower than said upper level 22 until the degree of engagement is no longer substantially constant. This takes place during intervals a-b. This can also be expressed as studying the derivative for the degree of engagement and when the derivative has been substantially zero for a certain first time period, the control signal is changed (reduced) until the derivative is no longer substantially zero.
    When the engagement rate is no longer substantially constant, ie. the derivative of the degree of engagement is no longer substantially zero, but thus decreases, the control signal 16 to the oil pump unit 18 is changed again to achieve maximum engagement, at time b.
    In the time interval b-c, the control signal 16 is maximum, i.e. maximum oil is pumped into the viscous coupling. When the switch-on degree has been constant longer than Atl (not exposed in the figure), at time c, the control signal 16 again changes to produce a switch-on degree lower than level 22. At time d the control signal 16 again changes maximum so that at time e it returns to a lower level.
    At time t2, the desired connection level 14 changes to a lower level.
    According to one embodiment, substantially constant means that the degree of engagement varies at most 5%.
    The first time period Atl is preferably shorter than 30 seconds, e.g. about 5 seconds, but must be long enough to calculate the degree of connection.
    According to the invention, the oil level in the viscous coupling is thus regulated so that it is just enough to achieve the desired high coupling level. A faster disconnection is then achieved because a smaller amount of oil needs to be pumped out of the viscous clutch.
    If the desired degree of engagement 14 is instead lower than an adjustable lower level 24, the control device, according to one embodiment, is adapted to control the engagement of the viscous coupling according to a second control strategy which involves changing the control signal by allowing the control signal 16 to the oil pump unit 18 to provide minimal engagement (see Figure 2). ).
    This takes place at time t2 and as can be seen from the top graph, the desired switching degree 14 here is lower than the lower level 24 and the control signal 16 goes down to a minimum level (middle graph).
    The second control strategy means that when the engagement rate has been substantially constant longer than a predetermined second time period (At2), this level is determined for the engagement rate where it has been constant, and then the lower level can be changed to a level depending on the determined level. Preferably, the lower level 24 changes to a level below the constant measured degree of engagement with a predetermined offset value. This is illustrated in the figure as "o" and there, in the illustrated case, the level 24 is changed (lowered) to a level below the constant measured engagement degree.
    The second time period At2 is preferably shorter than 30 seconds, e.g. about 5 seconds, but must be long enough to calculate the degree of connection. At2 can be selected as to the same value as Atl.
    A variant of the second control strategy is that when disconnecting from the upper prohibited area, to a desired degree of connection which is within the permitted range by restricting all oil supply.
    According to another variant, you go step by step from fi ill connection, to the permitted orn council and then to the lower forbidden area.
    When the desired degree of connection is between said upper and lower level, the control device is adapted to regulate the viscous connection according to a predetermined normal control strategy, e.g. with a P1 or a PID controller, including an integral part. This normal control strategy will not be described here as it is done in a conventional manner.
    If the current degree of connection exceeds the said upper level, ie. the viscous coupling risks getting stuck in full connection, and a control signal to the oil pump regarding control is generated within the permitted control range, the integrating part of the control is monitored, and, according to another embodiment, the regulating device is adapted to store current value for the integrating part. If the integrator is then turned over a maximum limit, the regulator is switched off and all oil supply is throttled to release the viscous clutch from full clutch. When the viscous coupling is again detected within the controllable range, controller control continues, now with a faster response thanks to reduced integrator torque, ie. the integral part is reduced. If the pump is regulated back before the maximum limit for integrator torque is reached, the logic for the controller is reset.
    According to one embodiment, the control device is adapted to control the degree of connection for a viscous connection arranged in connection with a coolant pump. The control device can of course also be used to regulate a viscous connection in connection with, for example, a fl genuine.
    The invention further comprises a vehicle comprising an internal combustion engine 30 and a coolant pump 32 for cooling the engine and which is driven via a viscous coupling 4 which is controlled by a control device 2 as described above. Often the oil pump unit 18 is an integral part of the viscous coupling 4.
    The present invention also encompasses a method of controlling a viscous coupling comprising a primary disk and a secondary disk, the primary disk having a first rotational speed and the secondary disk having a second rotational speed.
    Figures 3-5 show simplified fate diagrams intended to illustrate various embodiments of the present invention.
    The method comprises: - determining a current degree of engagement between the primary disk and the secondary disk, for example as the ratio between said second and first rotational speeds, - controlling the degree of engagement between the disks depending on a desired degree of engagement by controlling the amount of viscous oil between the disks an oil pump unit adapted to pump oil into the viscous coupling depending on the control signal.
    With reference to Figure 3, the method according to the invention further comprises that: - if the desired degree of engagement is higher than an adjustable upper level, regulate the engagement of the viscous coupling according to a first control strategy which involves alternately changing the control signal by first generating a control signal to the oil pump unit for maximum engagement and then, when the engagement rate has been substantially constant for longer than a predetermined first time period (Atl), change the control signal to provide an engagement rate lower than said upper level until the engagement rate is no longer substantially constant. This embodiment is discussed in more detail above, including with reference to the graphs shown in Figure 2.
    According to a further embodiment of the invention, illustrated by the fate diagram in Figure 4, the method comprises that if a desired degree of engagement is lower than an adjustable lower level, the engagement of the viscous coupling is regulated according to a second control strategy which changes the control signal to the minimum oil pump. connection. The second control strategy also means that when the engagement rate has been substantially constant longer than a predetermined second time period (At2) determining this level for the engagement rate where it has been constant, and changing the lower level to a level depending on the determined level. Here, too, reference is made to Figure 2 and to the description above.
    According to a further embodiment of the invention, which is illustrated by the fate diagram in figure 5, when a desired degree of connection is between said upper and lower level, the control device is adapted to control the viscous connection according to a predetermined normal control strategy including an integral part.
    If the current connection degree then exceeds said upper level, the current value of the integrating part is stored. If the integrator is then turned over a maximum limit, the regulator is switched off and all oil supply is throttled to release the viscous clutch from full clutch. When the viscous coupling is again detected within the controllable range, controller control continues, now with a faster response thanks to reduced integrator torque, ie. the integral part is reduced. If the pump is regulated back before the maximum limit for integrator torque is reached, the logic for the controller is reset.
    The method according to the present invention is preferably adapted to control the degree of connection for a viscous connection arranged in connection with a coolant pump. The present invention is not limited to the above-described preferred embodiments.
    Various alternatives, modifications and equivalents can be used. The embodiments above should therefore not be construed as limiting the scope of the invention, which is defined by the appended claims.
    权利要求:
    Claims (19)
    [1]
    A control device (2) for a viscous coupling (4) comprising a primary disk (6) and a secondary disk (8), the primary disk having a first rotational speed (10) and the secondary disk having a second rotational speed (12), said control device ( 2) is adapted to receive signals regarding said rotational speeds and regarding a desired degree of engagement (14), wherein the control device (2) is adapted to determine a current engagement degree (15) between the primary disk (6) and the secondary disk (8), and wherein the engagement degree between the disks are controlled by the control device (2) depending on a desired degree of engagement (14) by regulating an amount of viscous oil between the disks by delivering a control signal (16) to an oil pump unit (18) adapted to pump oil (20) into the viscous coupling (4) in dependence on the control signal, characterized in that when the desired degree of engagement (14) is higher than an upper level (22), the control device is adapted to regulate the viscous coupling in connection according to a first control strategy which involves alternately changing the control signal (16) by first generating a control signal (16) to the oil pump unit for maximum connection and then, when the degree of connection has been substantially constant longer than a predetermined first time period (Atl), changing the control signal (16). ) to provide a degree of engagement lower than said upper level (22) until the degree of engagement is no longer substantially constant.
    [2]
    The control device according to claim 1, wherein if a desired degree of engagement is lower than a lower level (24), the control device is adapted to control the engagement of the viscous coupling according to a second control strategy which involves changing the control signal (16) by letting the control signal (16) to the oil pump unit (18) provide minimal engagement.
    [3]
    The control device according to claim 2, wherein the second control strategy further comprises that when the engagement rate has been substantially constant longer than a predetermined second time period (At2) determining this level for the engagement rate where it has been constant, and changing the lower level to a level depending on the determined level.
    [4]
    The control device according to any one of claims 1-3, wherein said first time period (Atl) is shorter than 30 seconds. 10 15 20 25 30 14
    [5]
    The control device according to claim 3, wherein said second time period (At2) is shorter than 30 seconds.
    [6]
    The control device according to any one of the preceding claims, wherein the fact that the degree of engagement has been substantially constant means that the degree of engagement varies at most 5%.
    [7]
    The control device according to claim 2, wherein when a desired degree of engagement is between said upper (22) and lower (24) level, the control device is adapted to control the viscous coupling (4) according to a predetermined normal control strategy comprising an integral part.
    [8]
    The control device according to claim 7, wherein when the current degree of engagement exceeds said upper level (22), the current value of the integrating part is stored, and a control signal (16) to the oil pump unit (18) for full disconnection is generated, and the integrating part of the normal the control strategy is reduced to a value lower than the stored value.
    [9]
    The control device according to any one of the preceding claims, wherein the device is adapted to control the degree of engagement of a viscous coupling (4) arranged in connection with a coolant pump.
    [10]
    A vehicle comprising an internal combustion engine (30) and a coolant pump (32) for cooling the engine and which is driven via a viscous coupling (4) which is controlled by a control device (2) according to any one of claims 1-9.
    [11]
    A method of controlling a viscous coupling comprising a primary disk and a secondary disk, the primary disk having a first rotational speed and the secondary disk having a second rotational speed, the method comprising: - determining a current degree of connection between the primary disk and the secondary disk, - controlling the degree of connection between the disks depending on a desired degree of engagement by controlling the amount of viscous oil between the disks by delivering a control signal to an oil pump unit adapted to pump oil into the viscous coupling depending on the control signal, characterized in that the method further comprises that: - when the desired engagement is higher than an upper level, regulate the engagement of the viscous according to a first control strategy which involves alternately changing the control signal by first generating a control signal to the oil pump unit for maximum engagement and then, when the engagement has been substantially constant longer than a f predetermined first time period (Atl), change the control signal to produce a degree of engagement lower than said upper level until the degree of engagement is no longer substantially constant.
    [12]
    The method of claim 1, wherein the method comprises, when a desired degree of engagement is lower than a lower level, regulating the engagement of the viscous coupling according to a second control strategy which involves changing the control signal by allowing the control signal to the oil pump unit to provide minimal engagement.
    [13]
    The method of claim 12, wherein the second control strategy also means that when the engagement rate has been substantially constant longer than a predetermined second time period (At2) determining this level for the engagement rate where it has been constant, and changing the lower level to a level depending on the determined level.
    [14]
    The method of any of claims 1-13, wherein said first time period (Atl) is less than 30 seconds.
    [15]
    The method of claim 13, wherein said second time period (At2) is less than 30 seconds.
    [16]
    The method according to any one of claims 11-15, wherein substantially constant means that the degree of engagement varies at most 5%.
    [17]
    The method according to claim 12, wherein the method comprises, when a desired degree of engagement is between said upper and lower levels, regulating the viscous coupling according to a predetermined normal control strategy comprising an integral part. 10 16
    [18]
    The method of claim 17, wherein the method comprises, if the current degree of engagement exceeds said upper level, storing the current value of the integral part, and generating a control signal to the oil pump for full disconnection, and reducing the integral part of the normal control strategy to a value lower than the stored value.
    [19]
    The method according to any one of claims 11-18, wherein the method is adapted to control the degree of engagement of a viscous coupling arranged in connection with a coolant pump.
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    同族专利:
    公开号 | 公开日
    EP2798234B1|2018-02-21|
    WO2013095264A1|2013-06-27|
    US20150034444A1|2015-02-05|
    CN104126078A|2014-10-29|
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    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    SE1151225A|SE536262C2|2011-12-20|2011-12-20|Control device, and method in conjunction with a control device, for controlling a visco coupling|SE1151225A| SE536262C2|2011-12-20|2011-12-20|Control device, and method in conjunction with a control device, for controlling a visco coupling|
    EP12860041.8A| EP2798234B1|2011-12-20|2012-12-10|Regulator device, and method pertaining to a regulator device, for control of a viscous coupling unit|
    US14/366,781| US20150034444A1|2011-12-20|2012-12-10|Regulator device, and method pertaining to a regulator device, for control of a viscous coupling unit|
    PCT/SE2012/051363| WO2013095264A1|2011-12-20|2012-12-10|Regulator device, and method pertaining to a regulator device, for control of a viscous coupling unit|
    CN201280070212.6A| CN104126078A|2011-12-20|2012-12-10|Regulator device and method for control viscous coupling unit|
    BR112014014721-3A| BR112014014721B1|2011-12-20|2012-12-10|adjustment device for a visco-coupling|
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