This application claims priority from Japanese Patent Application No. 2017-248491 filed on Dec. 25, 2017. The application is incorporated herein by reference in its entirety.
The present invention relates to a vehicle door latch apparatus. In particular, the present invention relates to a vehicle door latch apparatus that reduces release operation force that is required to disengage a ratchet from a latch.
In a typical prior art vehicle door latch apparatus, a ratchet engages a latch that has rotated from an unlatched position to a full-latched position, and thereby prevents the latch from rotating in a releasing direction in order to keep the vehicle door closed (in the full-latched state). Further, in the vehicle door latch apparatus, the ratchet is rotated in the latch releasing direction (a direction opposite to the latch engaging direction), by a manual release operation force from a door opening handle or by an electric release operation force from a power release mechanism, to disengage the ratchet from the latch, and thereby allows the latch to rotate in the releasing direction to make the vehicle door openable.
The latch is strongly pressed against the ratchet in the full-latched state by being strongly biased in the releasing direction by the resilient force of a latch spring and by the repulsive force of a seal member that is provided between the door and the vehicle body. The ratchet is also biased in the latch engaging direction by the resilient force of a ratchet spring. The friction force, which is generated by the latch being pressed against ratchet, and the elasticity of the ratchet spring act as resistive force against the release operation force, resulting in degradation of the operation feeling when operating the door opening handle and in an increase in the size of the power release mechanism.
Patent Document 1 discloses a vehicle door latch apparatus that reduces the release operation force for releasing a ratchet from a latch.
Release component force E is set to be higher than the engagement keeping force that keeps ratchet B engaged with latch A, specifically, the sum of the friction force that is generated between latch A and ratchet B and the resilient force of the ratchet spring that biases ratchet B in the latch engaging direction. Therefore, when ratchet restraint C is rotated clockwise by the manual release operation force or by the electric release operation force in order to disengage ratchet restraint C from ratchet B, ratchet B is rotated in the latch releasing direction by release component force E and is pushed out from the latch engaging position to a latch disengaging position. As a result, ratchet B is disengaged from latch A, and the door is made openable.
In the configuration disclosed in Patent Document 1, the friction force that is generated between ratchet restraint C and ratchet B acts as force that is resistive against the release operation force. However, the resistive force is considerably reduced as compared to the force that is resistive against the release operation force in a conventional apparatus, that is, the friction force that is generated by the latch pressing the ratchet and the resistive force that arises from the elasticity of the ratchet spring, and accordingly, the release operation force can be reduced considerably.
Patent Document 1: DE102007045228A1
In the configuration of
Here, suppose that another engaging portion, specifically, a half latch engaging portion is arranged together with engaging portion F. Per this assumption, when ratchet B engages the half latch engaging portion, ratchet B, which is held by ratchet restraint C such that it cannot be disengaged from the latch, is mechanically locked by the half latch engaging portion. Therefore, the mechanically locked state of ratchet B cannot be released by a normal operation, and it is necessary to rotate ratchet restraint C by the manual release operation force or by the electric release operation force. This makes it difficult to use a typical latch that has a half latch engaging portion and a full latch engaging portion that are arranged on the outer circumference thereof.
A vehicle door latch apparatus according to a first aspect of the invention comprises:
a latch that is engaged with a striker and that is rotatable from an unlatched position to a full-latched over rotating position;
a ratchet member that is rotatably supported by a ratchet shaft and that has a pawl portion, wherein the pawl portion is movable between a latch engaging position, where the pawl portion can face a full latch engaging portion of the latch, and a latch releasing position, where the pawl portion is not in contact with the full latch engaging portion, wherein release component force is generated in a latch releasing direction when latch return force is applied in a releasing direction at the latch engaging position, and the ratchet member is pushed out from the latch engaging position to the latch releasing position by the release component force;
a ratchet restraint that is arranged on a side of the ratchet member and that can be moved about a pin between a block position and a release position, wherein at the block position, the ratchet restraint abuts against the ratchet member to prevent the ratchet member from moving from a latch engaging position, where the ratchet member engages the latch due to the release component force, to a latch disengaging position, and at the release position, the ratchet restraint is detached from the latch member to allow the latch member to move from the latch engaging position to the latch disengaging position, and
the ratchet restraint has a pole lever, wherein the pole lever can be disengaged from the full latch engaging portion by rotating about a connecting shaft in a latch disengaging direction when the ratchet restraint is at the block position.
According to the vehicle door latch apparatus of the second aspect of the invention, in the invention of the vehicle door latch apparatus of the first aspect, the latch has a half latch engaging portion that is arranged together with the full latch engaging portion.
According to the vehicle door latch apparatus of the third aspect of the invention, in the invention of the vehicle door latch apparatus of the first or second aspect, the ratchet restraint has a blocking surface, which is an arc surface whose center is positioned at the pin, and an inclined cam surface that extends contiguous with the blocking surface and whose radius from the pin gradually decreases.
According to the vehicle door latch apparatus of the fourth aspect of the invention, in the invention of the vehicle door latch apparatus of any one of the first to third aspects, the ratchet member has a base lever that is rotatably supported by a ratchet shaft, and the pole lever is rotatably supported on the base lever by the connecting shaft.
According to the vehicle door latch apparatus of the fifth aspect of the invention, in the invention of the vehicle door latch apparatus of the fourth aspect, the base lever is pressed against the base lever in a latch engaging direction by resilient force of a ratchet spring, a coil portion of the ratchet spring is supported by the connecting shaft, one of spring legs of the ratchet spring is engaged with ratchet shaft, and the other is engaged with the pole lever.
According to the vehicle door latch apparatus of the sixth aspect of the invention, in the invention of the vehicle door latch apparatus of the fifth aspect, the base lever can be rotated from a restricted position, where the base lever is in contact with the blocking surface, to a non-restricted position by the releasing component force.
According to the vehicle door latch apparatus of the seventh aspect of the invention, in the invention of the vehicle door latch apparatus of the sixth aspect, the ratchet restraint includes a cam biasing spring that biases the ratchet restraint from the release position toward the block position.
According to the vehicle door latch apparatus of the eighth aspect of the invention, in the invention of the vehicle door latch apparatus of the seventh aspect, the inclined cam surface of the ratchet restraint returns the base lever from the unrestricted position to the restricted position when the ratchet restraint is returned to the block position from the release position by resilient force of the cam biasing spring.
According to the vehicle door latch apparatus of the ninth aspect of the invention, in the invention of the vehicle door latch apparatus of any one of the first to eighth aspects, the ratchet restraint can be shifted from either the block position or the release position to the other by manual release operation force.
According to the vehicle door latch apparatus of the first aspect of the present invention, in the configuration in which ratchet member 15 is prevented from moving to the latch releasing position by ratchet restraint 21, pawl portion 15a of ratchet member 15 can be disengaged from latch 13 while holding ratchet restraint 21 at the block position.
According to the vehicle door latch apparatus of the second aspect of the present invention, half latch engaging portion 13c and full latch engaging portion 13d can be arranged side by side in latch 13.
According to the vehicle door latch apparatus of the third aspect of the present invention, blocking surface 21c ensures that ratchet member 15 is prevented from moving to the latch releasing position, and ratchet member 15 can be easily returned by inclined cam surface 21d.
According to the vehicle door latch apparatus of the fourth aspect of the present invention, pole lever 20 can be independently moved relative to base lever 19.
According to the vehicle door latch apparatus of the fifth aspect of the present invention, ratchet spring 17 can be rationally arranged without exerting a spring force on base lever 19.
According to the vehicle door latch apparatus of the sixth aspect of the present invention, pawl portion 15a can be easily disengaged from latch 13 by rotating base lever 19.
According to the vehicle door latch apparatus of the seventh aspect of the present invention, ratchet restraint 21 can be returned to the block position, which is the initial position, by cam biasing spring 23.
According to the vehicle door latch apparatus of the eighth aspect of the present invention, base lever 19 can be returned from the non-restricted position to the restricted position by the resilient force of cam biasing spring 23.
According to the vehicle door latch apparatus of the ninth aspect of the present invention, since ratchet restraint 21 can be operated by the manual releasing operation force, even if the electric operation is not available, the door opening operation and the door closing operation can still be performed.
The foregoing and other objects, features and advantages of the present application will become apparent from the following detailed description with reference to the accompanying drawings that illustrate the present application.
The present embodiment (one embodiment of the present invention) will be explained with reference to the drawings.
Ratchet member 15 is rotatably supported on the lower part of base plate 11 by ratchet shaft 16. Ratchet member 15 is biased in the latch engaging direction by ratchet spring 17 (shown by an arrow indicating the direction of resilience). In the unlatched state shown in
When the vehicle door is moved in the door closing direction, striker 18 that is fixed to the vehicle body (not shown) relatively enters horizontal striker entrance 11a that is formed in base plate 11 to abut against U-shaped striker engaging groove 13b of latch 13. Striker S then rotates latch 13 in the door closing direction (the full-latching direction, or the clockwise direction) against the resilient force of latch spring 14. Like typical well-known latches, latch 13 has half latch engaging portion 13c and full latch engaging portion 13d that are arranged on the outer circumference thereof.
Latch 13 normally rotates from the unlatched position shown in
After rotating to the over rotating position, latch 13 is returned in the releasing direction (the counterclockwise direction) by the resilient force of latch spring 14 and by the repulsive force of a seal member (not shown) that is provided between the door and the vehicle body. Full latch engaging portion 13d of latch 13 then abuts against pawl portion 15a at the latch engaging position, as shown in
The return force that is transmitted from full latch engaging portion 13d to pawl portion 15a is largely received as main component force F1 by ratchet shaft 16, as will be described later, but part of the return force is set to act as release component force F2 in a direction in which ratchet member 15 is pushed out in the latch releasing direction (the direction opposite to the latch engaging direction).
As shown in
The base portion of base lever 19 is rotatably supported by ratchet shaft 16, and the base portion of pole lever 20 is rotatably supported on the end portion of base lever 19 by connecting shaft 15b. In the present embodiment, connecting shaft 15b is formed integral with pole lever 20, and connecting shaft 15b is inserted into shaft hole 19c that is formed in resin cover 19b. Pawl portion 15a is formed in metal plate 20a of pole lever 20.
Bifurcated portion 19d is formed at the end portion of metal plate 19a of base lever 19. Connecting shaft 15b of pole lever 20 is arranged inside of bifurcated portion 19d. Gap 24 that is formed between bifurcated portion 19d and pole lever 20 (see
As shown in
Ratchet member 15 has connecting shaft 15b that is arranged at an intermediate position in the length direction thereof and that rotataby supports base lever 19 and pole lever 20. Therefore, when release component force F2 is generated in ratchet member 15, release component force F2 that is directed in the latch releasing direction acts exclusively on connecting shaft 15b that is positioned at the intermediate position, to bend ratchet member 15 at the intermediate position, and disengages pawl portion 15a from full latch engaging portion 13d. Therefore, it is impossible for ratchet member 15 alone to keep latch 13 at the full-latched position.
Ratchet restraint 21 is disposed in the vicinity of the side of ratchet member 15. Ratchet restraint 21 keeps ratchet member 15 engaged with latch 13 by preventing ratchet member 15 from moving in the latch releasing direction. Ratchet restraint 21 is rotatably supported on base plate 11 by pin 22. Ratchet restraint 21 is an insert molded product that includes metal plate 21a and resin cover 21b. Resin cover 21b is omitted in
Metallic plate 21a of ratchet restraint 21 is formed to be a rotating cam. On the outer circumference of metal plate 21a, arc-shaped blocking surface 21c whose center is positioned at pin 22 and inclined cam surface 21d that extends contiguous with blocking surface 21c are formed. Inclined cam surface 21d is a cam surface whose radius from pin 22 gradually decreases. Blocking surface 21c and inclined cam surface 21d abut against one of outer walls 19e of bifurcated portion 19d of metal plate 19a.
Ratchet restraint 21 is rotatable between the block position shown in
When the release operation force is not exerted, ratchet restraint 21 is held at the block position that corresponds to the initial position by the resilient force of cam biasing spring 23. At the block position, blocking surface 21c of ratchet restraint 21 is located on an extension line along which connecting shaft 15b of ratchet member 15 is moved by release component force F2.
In the door closed state in
In the door closed state in
When ratchet restraint 21 is rotated in the releasing direction, blocking surface 21c that faces and that is in contact with outer wall 19e moves out of the line of action of release component force F2 that acts on connecting shaft 15b. Then, base lever 19 (metallic plate 19a) rotates in the latch releasing direction such that it can move from the restricted position to the unrestricted position and such that connecting shaft 15b can move in the latch releasing direction along releasing component force F2. As a result, ratchet member 15 is bent at the intermediate position. Pawl portion 15a is flipped out of full latch engaging portion 13d in the latch releasing direction, and, as shown in
After latch 13 is rotated in the latch releasing direction, the manual release operation force or the electric release operation force acting on ratchet restraint 21 is disconnected. Then, ratchet restraint 21 is rotated in the direction opposite to the latch releasing direction back to the block position by the resilient force of cam biasing spring 23. Inclined cam surface 21d that is rotated in the direction opposite to the releasing direction then presses outer wall 19e to return base lever 19 from the non-restricted position to the restricted position by pushing base lever 19 in the latch engaging direction. As shown in
In the door opened state shown in
When latch 13 is at the half-latched position shown in
In the half latch state, pawl portion 15a can be disengaged from half latch engaging portion 13c by rotating latch 13 toward the full-latched position. By pushing out latch 13 toward the full-latched position, connecting slope 13e that is formed between half latch engaging portion 13c and full latch engaging portion 13d abuts against pole lever 20. Since gap 24 is formed between pole lever 20 and bifurcated portion 19d, pole lever 20 is then independently pushed out in the latch releasing direction, without rotating base lever 19, due to contact with connecting slope 13e. As a result, pawl portion 15a is disengaged from half latch engaging portion 13c.
Therefore, in the configuration in which ratchet restraint 21 prevents ratchet member 15 from moving in the latch releasing direction, half latch engaging portion 13c and half latch engaging portion 13d can be arranged on the outer circumference of latch 13.
When ratchet restraint 21 is mainly rotated by the power release mechanism, cam biasing spring 23 may be omitted. In this case, after rotating ratchet restraint 21 from the block position to the release position, the power release mechanism returns ratchet restraint 21 from the release position to the block position. In this control operation, it is possible to use rotational position control, such as a limit switch or a contact stopper, or time-controlled rotational position control. When the power release mechanism is used, it is also possible to rotate ratchet restraint 21 360 degrees from the block position and to stop ratchet restraint 21 again at the block position. This configuration is advantageous in terms of both the structural and control aspects because the rotation is limited to one direction. In the case of rotating ratchet restraint 21 360 degrees, in addition to inclined cam surface 21d that is detached from base lever 19 to allow base lever 19 to move to the non-restricted position, ratchet restraint 21 has an additional inclined cam surface that pushes base lever 19 back to the restricted position.
An embodiment in which ratchet restraint 21 is connected to door key cylinder 25 is shown in
Since electrical components, such as a power release mechanism that is coupled to ratchet restraint 21, cannot be completely free of electrical problems, it is desirable that ratchet restraint 21 be coupled both to the power release mechanism and to door key cylinder 25. By doing so, even if the power release mechanism becomes inoperable during operation, it is possible to rotate door key cylinder 25 in the releasing direction to move ratchet restraint 21 to the release position, thereby to move ratchet member 15 to the latch releasing position, and thereby to release latch 13 to make the vehicle door openable. In addition, since ratchet restraint 21 can be returned to the block position, which is the initial position, by rotating back door key cylinder 25 after the vehicle door is opened, the vehicle door can be stably closed next time.
In the above description, the friction force between ratchet member 15 and ratchet restraint 21, which is generated when ratchet restraint 21 is rotated from the block position in
The latch returning force for latch 13 is transmitted as external force P1 from the contact point between full latch engaging portion 13d and pawl portion 15a to connecting shaft 15b, and is then transmitted as external force P2 from connecting shaft 15b to ratchet shaft 16. These external forces P1 and P2 are separated into main component force F1 and release component force F2.
Pawl portion 15a may engage full latch engaging portion 13d either at a deep position or at a shallow position. Therefore, in a strict sense, the contact point of pawl portion 15a is different each time. Such variation of the contact point leads to the variation of the direction and the strength of external force P1 that is transmitted to connecting shaft 15b. The same applies to the direction of external force P2. As a result, main component force F1 and release component force F2 are variable.
In order to avoid such variation, pawl portion 15a of the present embodiment is formed as an arc surface whose center is positioned at connecting shaft 15b. By forming pawl portion 15a as an arc surface, even if the position where pawl portion 15a engages full latch engaging portion 13d is shifted, external force P1 always acts on the axial center of connecting shaft 15b. As a result, the direction and the strength of external force P1 is stabilized, and a change in external force P2, main component force F1 and release component force F2 can be prevented. Since release component force F2 becomes constant, the contact pressure between ratchet restraint 21 and ratchet member 15 becomes constant, and the release operation force of ratchet restraint 21 stably acts on ratchet member 15.
The latch returning force is transmitted to ratchet member 15 both from full latch engaging portion 13d and from half latch engaging portion 13c. Although some part of the above explanation only refers to the relationship between full latch engaging portion 13d and pawl portion 15a, the same applies to the relationship between half latch engaging portion 13c and pawl portion 15a.
Number | Date | Country | Kind |
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2017-248491 | Dec 2017 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2018/010866 | 3/19/2018 | WO | 00 |