JP2004286206A - Brake for vehicle - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a brake for a vehicle such as a carriage or a wheelchair in a simple structure. <P>SOLUTION: A bake mechanism comprises a pair of brake shoes 30 mounted on a base 10a mounted on a base plate 1a so as to be turnable and abutment possible on the front and rear parts of a rear wheel 3b and wire pins 41 mounted at the ends of the pair of brake shoes 30. A wire 40 is connected between the wire pins 41 in the state of inserting a spring 20 therethrough. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a brake for a vehicle such as a bogie or a wheelchair.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, in the case of a trolley for carrying luggage, for example, three to four wheels are provided, and the vehicle travels substantially horizontally to carry the luggage by pushing a handle.
[0003]
[Problems to be solved by the invention]
However, if the truck is placed on an inclined road or the like, the truck travels on the inclined road, so a brake is required as a safety device. Therefore, the present invention provides such a brake mechanism.
[0004]
[Means for Solving the Problems]
In the brake mechanism attached to the vehicle according to the first aspect, a pair of brake shoes that are rotatable and that can be brought into contact with front and rear wheels are attached to a base attached to a base plate or the like. A wire pin is attached to an end of the pair of brake shoes, and a wire is connected with a spring inserted between the wire pins.
The brake shoe normally keeps the locked state by pressing the wheel by a spring, but is pulled to the unlocked state by pulling the wire, so that it can run.
Further, as shown in FIG. 30, a brake for a vehicle according to claim 2 is provided with a pair of brake shoes that are rotatably provided on a base plate or the like and that can be brought into contact with front and rear of fixed rear wheels. It is attached to the connector.
Also, since the brake shoe is always provided with a tension spring through a connecting body so as to be able to abut on the wheel, and the connecting body and the connecting body are connected via a communication shaft rod, a symmetrical left and right through this connecting body is provided. In this state, the brake shoe abuts the wheel, and when the wire is pulled, the brake shoe disengages from the wheel via the communication body.
[0005]
In a third aspect of the present invention, a brake mechanism mounted on a vehicle is provided with a base and a brake base rotatably mounted on a base plate or the like. And the shoe body which can be contacted with the shoulder of the wheel is attached to the brake base, a spring is inserted between the brake base and the base, and a wire is connected to the brake base. is there.
For this reason, the shoe body always keeps the locked state by pressing the wheel with the spring, but the shoe body is unlocked by pulling the wire, and can run.
[0006]
The brake mechanism attached to the vehicle according to claim 4 is capable of traveling by attaching a front wheel and a fixed rear wheel to a back surface of the base plate, and is rotatable and fixed to a base attached to the base plate or the like. A spring is provided so that the shoe body can always contact the rear wheel before and after the rear wheel. Then, a wire pin is attached to the end of the pair of brake shoes, and the wire 40 is inserted into the wire hole 42b formed in the wire pin 41b and the inside of the cylindrical body 44, and the tip of the wire 40 is fixed with a wire stopper 45. Fix with.
Further, the wire 40 inserted through the wire hole 42b is inserted through the wire hole 42a formed in the wire pin 41a, and after exiting the wire hole 42a, is inserted into the cover body 57 having the metal terminal 56.
[0007]
Normally, the shoe body comes into contact with the rear wheel and is in a locked state due to the tensile force of the spring. However, when the wire is pulled, the shoe main body 31b is pressed by the cylindrical body 44, and a clockwise turning moment is generated about the fixing pin 12b as a base axis. Since the length of the wire 40 between the wire hole 42a and the wire hole 42b is substantially constant by the body 44 and the metal terminal 56, the shoe body 31a is pressed by the metal terminal 56, and the fixing pin 12a is used as a base axis. A counterclockwise turning moment is generated, and the shoe body 31a is detached from the rear wheel 3b to be in an unlocked state. That is, both shoe bodies 31a and 31b are in an unlocked state.
[0008]
The brake mechanism attached to the vehicle according to claim 5 is a vehicle that can travel by attaching a front wheel and a fixed rear wheel to the back surface of the base plate, and between the base attached to the base plate and the lower bracket 82. The spring 83 is inserted. Under the lower bracket 82, the inverted V-shaped brake pieces 85a and 85b are supported by the wire 40.
Normally, one of the brake pieces 85a and 85b bites into the rear wheel due to the repulsive force of the spring and is in a locked state. However, the wire is pulled to be in an unlocked state.
[0009]
In the brake mechanism mounted on a vehicle according to the sixth aspect, wheels are rotatably mounted on casters mounted on a base plate or the like. And, in the space above the caster, a brake shoe forming a wave portion that can contact the wheel is inserted, and a spring is inserted between the caster and the brake shoe. The wheel is being pressed. A wire for unlocking the brake shoe is attached to the brake shoe.
When the wire is pulled, the wave portion of the brake shoe separates from the wheel and is unlocked (brake released). On the other hand, when the pulling of the wire is stopped, the wave portion of the brake shoe comes into contact with the wheel by the spring and is locked.
[0010]
The brake mechanism attached to the vehicle according to claim 7 is a brake mechanism for stopping a universal wheel attached to a universal caster, and by providing a brake shoe that can be contacted from above the universal wheel, the direction of the universal wheel can be changed. In this case, the brake shoes can be brought into contact with each other to bring them into a locked state (brake).
[0011]
The brake mechanism attached to the vehicle according to claim 8 is provided with a brake shoe that can contact a wheel, and a wire is connected to the brake shoe, and the wire is connected to a brake lever. When the lever is depressed, the brake shoe is operated to be in a locked (or unlocked) state.
A lock block 208 is fixed to a rotation shaft 205a that is rotated by the lock lever 205, and a long hole is formed in the upper plate 203 fixed to the handle, and the rotation shaft 205a is inserted. Therefore, the rotating shaft 205a can reciprocate between the long holes. On both sides of the lock block body 208, an L-shaped operating body 209 that can reciprocate with the wire is provided.
[0012]
Then, when the lock lever 205 is rotated to form a gap between the lock block body 208 and the operation body 209, both the operation body 209 and the rotation shaft 205a can reciprocate. Therefore, when the wire is pulled by grasping one of the brake levers, the operating body 209 and the rotating shaft 205a are both reciprocally movable mechanisms. Works.
[0013]
The brake mechanism attached to the vehicle according to the ninth aspect is a brake shoe that can contact both sides when inserted from above the wheel, and the brake shoe has a tapered portion narrowing from a lower portion to an upper portion. Therefore, as the wheel rotates, the brake shoe cuts into the tapered portion formed in the brake shoe.
[0014]
The brake mechanism attached to the vehicle according to the tenth aspect is provided with a pair of brake shoes that can be abutted on both sides of the wheel, and the lower portions of the pair of brake shoes swing through holding members 192a and 192b. Since it is movable and the upper part is connected by a tension spring, the lower ends 191a and 191b of the brake shoes are put on both sides of the wheel 3 to be in a braking state. On the other hand, when the wire is pulled, the lower ends 191a and 191b of the brake shoes are detached from both sides of the wheel 3, and the brake is released.
[0015]
In the vehicle according to the eleventh aspect, an operation body 305 is attached to an operation plate 303 that is rotated about a rotation shaft 302 by a wire 210 that is constantly pulled downward. A rotatable receiving body 311 is attached to the handle 19, and a groove 312 that can support the operating body 305 is formed in the receiving body 311. Then, the brake is locked and unlocked between when the operation body 305 is attached to the groove 312 and when the operation body 305 is detached. When the operating body 305 is attached to the groove 312, the wire 210 is pulled upward, and when the operating body 305 is detached from the groove 312, the wire 210 is pulled downward. Can be locked and unlocked via.
[0016]
A vehicle according to a twelfth aspect is a vehicle brake in which the brake shoes 175a and 175b are brought into a brake state and a release state with respect to the wheel 3 by the elevation of the operating body 321. The base 322 fixed to the handle 19 and the operating body 321 are connected by a link body 323. Therefore, when the operating body 321 is lifted, the link body 323 is rotated, and the brake shoes 175a and 175b are separated (lifted) from the wheels 3, and when the operating body 321 is lowered, the link body 323 is rotated and the brake is released. The shoes 175a and 175b press the wheels to apply a brake.
[0017]
In the vehicle according to the thirteenth aspect, an L-shaped flat plate-shaped brake body 331 is provided below the base plate 1a, the end of which is fixed to the back surface of the base plate 1a, and which can contact the wheel 3. A support 332 is vertically provided on the back surface of the base plate 1a, and a spring for urging the brake body 331 toward the base plate is fitted into the support 332. Further, a foot pedal 336 rotatable via a rotating shaft 335 formed on the brake body 331 is attached. Further, a pressing body 338 for pressing the brake body 331 is attached to the foot step body 336.
Then, when the stepping body 336 is stepped downward, the stepping body 336 rotates counterclockwise about the rotation shaft 335 and stops at the stop body 337 while lowering (pressing) the brake body 331 by the pressing body 338. The end of the stepping body 336 abuts on the back surface of the base plate 1a to lock the brake body 331. Therefore, the brake body 331 contracts the spring 333 and descends, and the descending brake body 331 presses the wheel 3 to be in a brake state (lock state) (FIG. 28A).
On the other hand, when the release petal 331a is stepped on, the foot pedal 336 is detached from the back surface of the base plate 1a, and the foot pedal 336 is rotated by the torsion coil spring (not shown) mounted between the foot pedal 336 and the brake body 331. , The urging force for lowering (pressing) the brake body 331 by the pressing body 338 disappears, and the resilient force of the spring 333 raises the brake body 331 and separates from the wheel 3, so that the brake is released ( (Unlocked state) (FIG. 28B).
[0018]
In the brake of the vehicle according to the fourteenth aspect, an operating body 401 is provided along the handle 19, and brake shoes 175 a and 175 b capable of abutting on rear wheels are attached to the lower end of the operating body 401. An operation base 405 is mounted on the upper part of the operation body 401, and a handle base 403 is mounted on the handle 19, and these operation bases 405 and the handle base 403 are rotatably connected. The link lever 406 is provided.
Then, when the operating body 401 is raised, the brake shoes 175a and 175b separate from the wheels, and maintain the unlocked state via the link lever 406. On the other hand, when the link lever 406 is rotated by the operating body 401 to lower the operating body 401, the brake shoes 175a and 175b abut against the wheels to be in a braking state. It should be noted that the operation body 401 may be configured so as to be in a reverse locked or unlocked state when the operating body 401 is raised or lowered.
[0019]
BEST MODE FOR CARRYING OUT THE INVENTION
(First Embodiment)
An embodiment of the present invention will be described with reference to FIG. 1A showing a plan view and FIG. 1B showing a right side view.
The main body 1 of the truck is formed in a square shape by a frame frame assembled at an appropriate interval, and a base plate 1a made of thin steel or resin is fixed on the frame frame.
A pair of front wheels 3a is mounted on the front back side of the base plate 1a via a free caster 2, and a fixed rear wheel 3b is mounted on the back rear side of the base plate 1a. is there.
A rotatable inverted U-shaped handle 19 is attached to the frame behind the base plate 1a so as to be foldable.
[0020]
Next, regarding the brake mechanism 100 of the fixed rear wheel 3b, FIG. 2A showing the front, FIG. 2B showing the side, and FIG. 3A showing the brake mechanism viewed from the back side. Will be explained.
The mounting structure of the rear wheel 3b is a well-known structure, and the rear wheel 3b is rotatably mounted on an inverted U-shaped mounting bracket, and this mounting bracket is screwed to the back side of the base plate 1a. .
[0021]
The components of the brake mechanism 100 are a mounting body 10, a spring 20, a brake shoe 30, a wire 40, and a lock / unlock mechanism 50. The brake mechanism is provided between the front and rear of a rear wheel 3b via a base plate 1a and a frame. , The shoe body 31 of the brake shoe 30 comes into contact with the front and rear of the rear wheel 3b, and exerts a braking function for forward and backward movement.
The mounting body 10 will be described with reference to FIG. 4 (A) showing a left side surface and FIG. 4 (B) showing a plan view. The base 10a is a rectangular thin plate. A bolt hole 11a for fixing with a bolt 11 is formed on the back side of the plate 1a, and a pin hole 12a for inserting a fixing pin 12 shown in FIG. The body 13 is standing.
[0022]
Next, the brake shoe 30 will be described with reference to FIG. 4 (E) showing a left side surface and FIG. 4 (F) showing a plan view. The shoe body 31 is a thin rectangular plate. An overhang 33 is integrally formed with a pin hole 32 that can be attached to the base 10 a via the fixing pin 12. The overhang 33 can be attached to the outside of the fixed body 13.
A pin hole 35 is formed in a lower portion of the shoe body 31 so that a wire pin 41 connected to the wire 40 can be attached thereto. The wire pin 41 is provided with a wire hole 42 through which the wire 40 is inserted at the center as shown in FIG.
[0023]
In the brake mechanism 100 configured as described above, the brake shoe 30 is attached to the base 10a via the fixing pin 12. Next, the wire pin 41 is inserted through the shoe body 31 of the brake shoe 30.
Then, the wire 40 is inserted into a wire hole 42 formed in the wire pin 41 of the rear brake mechanism, and the spring 20 is passed through the wire 40. Further, the wire 40 is inserted through a wire hole 42 formed in the wire pin 41 of the front brake mechanism, and the distal end of the wire 40 is fixed with a wire stopper 45.
[0024]
Next, when the pair of brake mechanisms 100 are fixed to the back surface side of the base plate 1a with bolts 11, the pair of shoe bodies 31, 31 are brought into contact with the front and rear of the rear wheel 3b by the repulsive force of the spring 20. Locked. That is, the rotatable shoe main bodies 31, 31 are rotatable by the fixed pins 12 attached to the lower portion, and the springs 20 mounted between the wire pins 41, 41 provided at the upper positions of the fixed pins 12 are provided. Due to the repulsive force, these shoe bodies 31 are urged toward opposite sides to form a C-shape, and are brought into contact with the front and rear of the rear wheel 3b to be locked.
[0025]
The position (angle) at which the shoe body 31 contacts the rear wheel 3b is important, and it goes without saying that the position (angle) at which the shoe body 31 bites when the rear wheel 3b moves forward and backward is desirable. In order to more securely lock, it is desirable to attach a brake mechanism to both rear wheels 3b.
An extension piece 39 is attached to the shoe body 31 in consideration of the wear of the shoe body 31. An elongated hole is formed in the extension piece 39, and by adjusting the length of the shoe body 31 with a bolt 39a, the degree of braking can be adjusted.
[0026]
The end of the wire 40 is connected to a lock / unlock mechanism 50 attached to the grip bar 19a of the handle 19.
The lock / unlock mechanism 50 will be described with reference to FIG. 5 (a plan view and a side sectional view). The lock / unlock mechanism 50 includes a circular portion 51 conforming to the shape of the gripping bar 19a via a screw 52. Fixed. The lock / unlock mechanism 50 is provided with a rotatable S-shaped operation piece 53 attached to the screw 52, and is rotated via an operation lever 54 fixed to the operation piece 53.
At the end of the operation piece 53, a wire 40 connected to a brake mechanism attached to the pair of rear wheels 3b is fixed via a bolt nut 55. When the operation lever 54 is rotated, the wire 40 Is pulled.
[0027]
As shown in FIG. 3A, the shoe body 31 of the brake mechanism 100 is in a locked state in contact with the rear wheel 3b by the repulsive force of the spring 20, but rotates the operation lever 54. When the wire 40 is pulled, the one rotatable shoe body 31 pulls the wire pin 41 and rotates with the fixing pin 12. One shoe body 31 is rotated by the fixing pin 12 by the repulsive force of the spring 20. Therefore, the U-shaped shoe bodies 31, 31 in the locked state have a further expanded C-shape, are no longer in contact with the front and rear of the rear wheel 3b, and are in an unlocked state (FIG. 3). (B)).
As described above, although the lock state is always maintained by the simple brake mechanism, the lock state can be unlocked by the operation lever 54, so that safety can be ensured even when the bogie is stopped on an inclined road or the like. Can be.
Although the brake mechanism is mounted on the fixed rear wheel 3b, it may be mounted on a rotatable wheel.
[0028]
(Second embodiment)
Next, FIG. 6 ((A) is a side view in a locked state, (B) is a side view in an unlocked state, (C) is a front view, and (D) is a detailed view of the brake shoe 71). Will be described.
An inclined base 70 and a brake base 72 are attached to the back side of the base plate 1a via a fixed body 69 fixed to the base plate 1a so as to be rotatable about a rotary shaft 70a. A brake shoe 71 is mounted on the brake base 72 so that the brake shoe 71 can be brought into contact with both shoulders of the rear wheel 3b and can be brought into contact (bite) at two points at both ends.
The base 70 is provided with an adjustment bolt 75 through which a spring 73 is inserted. Depending on the position of the adjustment bolt 75, the reaction force of the spring 73 acts on the brake base 72, and the brake shoe 71 moves rearward. The pressing force for pressing the wheel 3b can be adjusted.
An end of a wire 40 is attached to the brake base 72, and the other end of the wire 40 is connected to the lock / unlock mechanism 50.
[0029]
In the brake mechanism having the above-described configuration, the brake shoe 71 normally presses the rear wheel 3b due to the repulsive force of the spring 73, and is in a locked state (FIG. 6A).
On the other hand, when the wire 40 is pulled through the lock / unlock mechanism 50, the brake base 72 is rotated by the rotation shaft 70a, and the brake shoe 71 is separated from the rear wheel 3b to be in an unlocked state (FIG. 6 (B)).
As described above, the lock state is always maintained by the simple brake mechanism, but the unlock state can be achieved by pulling the wire 40. Therefore, safety can be ensured even when the bogie is stopped on an inclined road or the like. Can be planned.
[0030]
When the end of the wire 40 is attached to the base 70 and the wire 40 is pulled, the base 70 hits the adjustment bolt 75 and the brake base 72 (brake shoe 71) is released from the rear wheel 3b. It may be configured in a state.
Further, the brake mechanism described above has a structure in which it is unlocked and locked through a wire, but may be constituted by a link mechanism or the like.
[0031]
(Third embodiment)
FIG. 7 shows a brake mechanism having another configuration. In the brake mechanism, the brake mechanism shown in the first embodiment (FIG. 3) uses one spring 20, and this spring 20 is always Unlike the rebound state, the pair of brake shoes 30a, 30b are provided with springs 20a, 20b independently of each other, and these springs 20a, 20b are always used in a tensioned state.
FIG. 7A is a locked state view of the brake mechanism viewed from the back side, and FIG. 7B is a side view of the locked state.
[0032]
The end of the spring 20a is attached to the wire pin 41a, and the other end is attached to the base 10a. Further, a brake piece 31c having a long hole 38 formed in the bottom plate of each of the shoe bodies 31a and 31b is fixed at an appropriate position with a screw (not shown) through the long hole 38 to thereby provide a brake piece. The protrusion length of 31c can be adjusted, and it can cope with wear of the fixed rear wheel 3b (FIG. 8C).
Therefore, the spring 20a generates a clockwise turning moment in the shoe body 31a about the fixing pin 12a, and the brake piece 31c attached to the shoe body 31a contacts the rear wheel 3b and is in a locked state. .
On the other hand, the end of the spring 20b is also attached to the wire pin 41b, and the other end is attached to the base 10a. Therefore, the shoe main body 31b generates a counterclockwise turning moment about the fixing pin 12b as a base axis, and the brake piece 31c attached to the shoe main body 31b abuts on the rear wheel 3b and is in a locked state.
[0033]
As shown in FIGS. 8A (plan view) and (B) (side view), the wire 40 is inserted through a wire hole 42b formed in a wire pin 41b, and is inserted through a metal cylinder 44. Then, the distal end of the wire 40 is fixed with a wire stopper 45.
On the other hand, the wire 40 inserted through the wire hole 42b is inserted through the wire hole 42a formed in the wire pin 41a and connected to the lock / unlock mechanism 50 provided in the first embodiment.
After exiting the wire hole 42a, the wire 40 is inserted into a cover body 57 having a metal terminal 56. The cover body 57 has such a hardness that the cover body 57 is slightly compressed even when a compressive force is applied. Therefore, the length of the wire 40 between the wire hole 42a and the wire hole 42b is substantially constant due to the cylindrical body 44 and the metal terminal 56.
[0034]
In the brake mechanism according to the third embodiment, the brake pieces 31c of the shoe bodies 31a and 31b of the brake mechanism 100 abut on the rear wheel 3b by the tensile force of the springs 20a and 20b, and are in a locked state.
Then, when the operation lever 54 is rotated to pull the wire 40, the shoe body 31b is pressed by the cylindrical body 44, and a clockwise turning moment is generated about the fixing pin 12b as a base axis, and the shoe body 31b is detached from the rear wheel 3b. To unlock.
[0035]
On the other hand, the position of the wire hole 42b is changed by the clockwise rotation of the shoe body 31b, but as described above, the wire between the wire hole 42a and the wire hole 42b is formed by the cylinder 44 and the metal terminal 56. Since the length of the shoe 40 is substantially constant, the shoe body 31a is pressed by the metal terminal 56 to generate a counterclockwise turning moment about the fixing pin 12a, and the shoe body 31a is detached from the rear wheel 3b. To unlock.
[0036]
As described above, the shoe bodies 31a and 31b are always in a locked state through the pulling force of the springs 20a and 20b, but by providing the wire 40 with the tubular body 44 and the metal terminal 56, one straight By pulling the appropriate wire 40, the unlocked state can be obtained.
Although the wire 40 has been described as being pulled toward the shoe body 31a in the above description, the wire 40 may be pulled toward the shoe body 31b. Also, without the cylindrical body 44 and the metal terminal 56, one straight wire 40 is provided with a wire stopper 45 on the wire hole 42a side, inserted through the wire hole 42b from the wire hole 42a, and rotated by the wire hole 42b. Then, it may be configured by a method of pulling again to the wire hole 42a side.
[0037]
(Fourth embodiment)
FIG. 9 (A) is a front view of a brake mechanism having another configuration, and FIG. 9 (B) is an enlarged view showing a lock mechanism using brake pieces 85a and 85b pressed from above fixed rear wheels 3b.
The inverted U-shaped upper metal fitting 81 is inserted into the space 90 formed by the support 89 on the rear surface side (lower side) of the base plate 1a above the rear wheel 3b, and is fixed with screws or the like. The wheel 3 is attached to a lower portion of the support 89 via a rotating shaft 3X.
On the other hand, the U-shaped lower fitting 82 is located inside the upper fitting 81, and a spring 83 is inserted between the upper fitting 81 and the lower fitting 82.
[0038]
In addition, the inverted V-shaped brake pieces 85a and 85b are not necessarily required to be rotatable below the lower metal fitting 82, but are mounted rotatably here. Is supported by a wire 40 having a wire stopper 45 attached thereto.
The wire 40 is inserted through the lower fitting 82 and the upper fitting 81 and connected to the lock / unlock mechanism 50 provided in the first embodiment. Also, the upper bracket 81 is not always necessary, and if not, the spring 83 is inserted between the base plate 1a and the lower bracket 82.
[0039]
In the brake mechanism having the above-described configuration, the reverse V-shaped brake pieces 85a and 85b are constantly pressed by the repulsive force of the spring 83 and hit the rear wheel 3b. In this state, when the rear wheel 3b rotates counterclockwise, the brake piece 85b separates from the rear wheel 3b, the lower bracket 82 moves upward, and makes contact at the lower corner (X) of the upper bracket 81. At the same time, the upper metal fitting 81 comes into contact with the base plate 1a, is prevented from rotating, and the brake piece 85a bites into the rear wheel 3b and is locked (FIG. 9C). If the upper metal member 81 is not provided, the lower metal member 82 comes into contact with the support member 89, and the brake piece 85a bites into the rear wheel 3b and is locked.
[0040]
On the other hand, when the rear wheel 3b rotates clockwise, the brake piece 85a separates from the rear wheel 3b, the lower bracket 82 moves upward, comes into contact with the lower corner (Y) of the upper bracket 81, and the upper bracket 81 Is in contact with the base plate 1a, the rotation thereof is prevented, and the brake piece 85b bites into the rear wheel 3b and is locked (FIG. 9D). If the upper metal member 81 is not provided, the lower metal member 82 comes into contact with the support member 89, and the brake piece 85b bites into the rear wheel 3b and is locked.
[0041]
Thus, no matter which direction the rear wheel 3b rotates, any one of the brake pieces 85a and 85b is locked in a state of biting into the rear wheel 3b, so that the brake is reliably applied.
When the wire 40 is pulled, the spring 83 is contracted, and the brake pieces 85a and 85b are separated from the rear wheel 3b to be in an unlocked state.
As described above, various types of bogie brake mechanisms have been presented, but all have a simple structure, always maintain a locked state, and when the wire is pulled, the vehicle is unlocked so that the vehicle can run, so that it is safe. It is a trolley.
The above-mentioned brake mechanism is applied to a fixed rear wheel. For a wheel that can freely rotate, the entire brake mechanism fixed to the base plate 1a is adjusted to the rotating wheel. What is necessary is just to comprise so that rotation is possible.
[0042]
Also, as shown in FIG. 9 (E), the brake mechanism shown in FIG. 9 (A) is attached to the lower part of the base plate 1a so as to be located outside the support 89 constituting the caster 2A. That is, in the brake mechanism, the upper metal member 81 is attached to the base plate 1a, a spring 83 is inserted between the upper metal member 81 and the lower metal member 82, and the lower metal member 82 has inverted V-shaped brake pieces 85a and 85b. Is mounted so as to be able to contact the wheel and is supported by the wire 40.
By attaching the upper fitting 81 to the base plate 1a in this manner, the brake mechanism can be positioned outside the support 89 (caster 2A), so that the brake mechanism can be easily attached to the carriage. The operation of this brake mechanism is the same as that of the brake mechanism shown in FIG.
[0043]
(Fifth embodiment)
The present embodiment is different from the fourth embodiment in that the upper fitting 81 is not provided and the lower fitting 82 is extended left and right to form an extended portion 82a.
Note that the protruding length of the extending portion 82a is a length that allows the brake pieces 85a and 85b to rotate and contact the support 89 to prevent the rotation.
In this brake mechanism, the reverse V-shaped brake pieces 85a and 85b are constantly pressed by the repulsive force of the spring 83 and hit the rear wheel 3b. In this state, when the rear wheel 3b rotates counterclockwise, the brake piece 85b separates from the rear wheel 3b, and the extended portion 82a of the lower metal fitting contacts the support 89 to prevent the rotation (X Part), the brake piece 85a bites into the rear wheel 3b and is locked (FIG. 10C).
[0044]
On the other hand, when the rear wheel 3b rotates clockwise, the brake piece 85a separates from the rear wheel 3b, and the extended portion 82a of the lower bracket abuts on the support 89 to prevent rotation (Y portion). 85b bites into the rear wheel 3b and is locked (FIG. 10D).
As described above, instead of the upper fitting 81 in the fourth embodiment, an extended portion 82a is formed in the lower fitting 82 to prevent the rotation of the brake pieces 85a and 85b. Good.
[0045]
(Sixth embodiment)
Next, the brake mechanism shown in FIG. 11 will be described. This brake mechanism is a brake mechanism for the universal wheel 3A attached to the universal caster 2.
The universal caster 2 is rotatably mounted on the base plate 1a, and the universal wheel 3A is rotatably mounted on the universal caster 2 via a fixed shaft 98.
In the upper space 99 of the universal caster 2, a brake shoe 110 having a wave portion 110a abutting on the universal wheel 3A at three places is attached.
Then, a spring 111 is inserted between the free caster 2 and the brake shoe 110, and the wave 110a of the brake shoe 110 normally presses the free wheel 3A by the pressing force of the spring 111 to maintain the locked state. Therefore, the brake shoe 110 and the universal wheel 3A maintain the same position, and rotate with the rotation of the universal caster 2.
In addition, a wire 40 for unlocking the brake shoe 110 by inserting and pulling the adjustable caster 2 is connected to the lock and unlock mechanism 50 shown in FIGS. I have.
[0046]
Next, the operation of the brake mechanism shown in FIG. 11 will be described. FIG. 11 (A) shows a state in which the brake shoe 110 is unlocked (brake release) in the lock and unlock mechanism 50 and the wire 40 is pulled. is there. By pulling the wire 40, the brake shoe 110 compresses the spring 111, the wave portion 110a of the brake shoe 110 is separated from the free wheel 3A, and the brake is released (unlocked) to allow free running.
[0047]
On the other hand, as shown in FIG. 11B, the wire 40 is relaxed by the lock / unlock mechanism 50, and the brake shoe 110 is locked (brake).
In this locked state, when the free wheel 3A is rotated in the counterclockwise direction, the brake shoe 110 causes the wave portion 110a on the left side of the brake shoe 110 to bite into the free wheel 3A, as shown in FIG. When the 3A is rotated clockwise, as shown in FIG. 11 (D), the brake shoe 110 has the corrugated portion 110a on the right side of the brake shoe 110 biting into the free wheel 3A, and maintains a firm brake state.
As described above, while the brake shoe 110 maintains the same position as the universal wheel 3A, the brake shoe 110 can be brought into the brake state by the universal caster 2 with respect to the universal wheel 3A which faces in any direction.
[0048]
(Seventh embodiment)
The present embodiment is a brake mechanism for a free wheel 3A attached to the free caster 2, and FIG. 12 (A) showing a side, FIG. 12 (B) showing a front, and FIG. 13 showing a partially enlarged front of a caster portion. A description will be given with reference to FIG.
In this cart (shopping cart) 150, a free caster 152 is rotatably attached to a lower part of an inverted U-shaped handle 151, and a free wheel 3A is rotatable about a fixed shaft 153 inserted through the free caster 152. It is attached. In addition, a frame 167 for reinforcement is provided horizontally on the handle 151.
A frame fastener 154 is attached to a lower portion of the handle 151, and a bottom frame 155 is stretched forward through the frame fastener 154. A free caster 152 is provided at a lower portion of the distal end. It is rotatably mounted.
The universal wheel 3A is rotatably mounted on a fixed shaft 153 inserted through the universal caster 152, and the universal caster 152 is rotatable forward and backward while rotating freely.
[0049]
On the other hand, a slide body 156 is attached to the rear side of the frame tightening body 154, and a brake rod 158 that moves up and down is inserted through an insertion hole formed in the slide body 156, and the slide body 156 is connected to the slide body 156 described later. A spring 163 is inserted between the mounting plates 160 and constantly urges the mounting plate 160 downward.
A ring-shaped brake shoe 159 that can press and contact from the upper part of the free wheel 3A in any direction is provided at the lower end of the brake rod 158 with an inverted U-shaped mounting plate 160 as a medium. It is attached with a nut 161. Note that the ring-shaped brake shoe 159 does not necessarily have to be circular, and may have any shape as long as it can cover the range in which the free wheel 3A (free caster) rotates.
Further, the ring-shaped brake shoe 159 is always in a brake state in which the ring-shaped brake shoe 159 is pressed downward by the own weight of the brake rod 158 and the gripping rod 162 described later and the repulsive force of the spring 163.
[0050]
Further, since the ring-shaped brake shoe 159 can be attached to the outside of the universal caster 152, it can be easily attached as a component. Further, the ring-shaped brake shoe 159 does not necessarily have to be circular, and may have any shape as long as it can cover the range in which the universal wheel 3A (the universal caster) rotates.
On the other hand, a grip bar 162 is attached to the upper part of the brake rod 158 through a link piece 164 attached to the handle 151 in a K-shape, while the lower end is connected to the brake rod 158 via a lever 169. It is.
When the horizontal bar of the handle 151 and the horizontal bar of the grip bar 162 are squeezed, the grip bar 162 and the brake bar 158 rise, and the ring-shaped brake shoe 159 separates from the free wheel 3A to release the brake.
[0051]
A stop piece 165 rotatable about a rotation shaft 156a is attached to the rear side of the frame fastening body 154. When the stop piece 165 is inserted under the lever 169, the grip bar 162 is raised. In this state, the brake rod 158 is prevented from descending, and the ring-shaped brake shoe 159 maintains the brake release of the universal wheel 3A, thereby enabling free running.
Therefore, in order to perform the brake release operation by operating the grip bar 162, it is necessary to keep the stop piece 165 detached from below the lever 169.
[0052]
As described above, by adopting the ring-shaped brake shoe 159 for the brake mechanism for stopping the free wheel 3A with the free caster of the bogie, the ring-shaped brake shoe is provided regardless of the direction of the free wheel 3A. 159 can be pressed downward from above to perform a braking action.
In this embodiment, the brake piece 158 is prevented from descending by the stop piece 165, and the brake release state can be maintained. By releasing the stop piece 165, the braked state is always maintained. I do. The brake is released by raising the grip bar 162. However, the brake can always be released.
[0053]
(Eighth embodiment)
This embodiment is a brake mechanism for the free wheel 3A attached to the free caster 2 and is a mechanism that can be changed to a locked and unlocked state by operating the foot pedal 195, and FIG. A), description will be given with reference to FIG. 15 showing the front locked state 14 (B) and the unlocked rear face.
[0054]
On the left and right sides of the lower part of the base plate 1a of the carriage 180, universal wheels 3A are attached via universal casters 181.
Further, a pin fixing body 182 having three grooves is attached to a lower center portion of the base plate 1a. A rotary shaft 186a is fitted in the left groove, a left operation plate 187a is mounted on one side of the rotary shaft 186a, and a substantially U-shaped arm 188a is mounted on the other end. , A ring-shaped brake shoe 190a is attached so as to be positioned on the universal wheel 3A.
Therefore, the left operation plate 187a and the brake shoe 190a are integrally formed, and are attached so as to be rotatable about a rotation shaft 186a. Also, no matter which direction the universal wheel 3A faces, when the brake shoe 190a descends, it comes into contact with the universal wheel 3A to perform a braking action.
[0055]
A rotation shaft 186b is fitted in a groove on the right side of the pin fixing body 182, and one side of the rotation shaft 186b is located on the back side of the left operation plate 187a and is provided with a right operation plate. 187b is mounted, and a ring-shaped brake shoe 190b is mounted on the other end of the universal wheel 3A via a substantially U-shaped arm 188b.
Therefore, the right operation plate 187b and the brake shoe 190b are integrally formed, and are mounted so as to be rotatable about a rotation shaft 186b. Also, no matter which direction the universal wheel 3A faces, when the brake shoe 190b descends, it comes into contact with the universal wheel 3A to perform a braking action.
[0056]
A spring 192 is stretched between the bent portions of the arms 188a and 188b, and is constantly pulled toward the center.
A brake petal shaft 196 is fitted in a central groove of the pin fixing body 182, and a foot pedal 195 is connected to the brake petal shaft 196, and a petal operation plate 197 is attached. The petal operation plate 197 is in contact with the left operation plate 187a and the right operation plate 187b, and is selected to have a length that can be pressed downward, and by pressing these operation plates downward, The brake shoes 190a, 190b rotate about the rotation shafts 186a, 186b, separate from the free wheel 3A, and enter the unlocked state.
In addition, a stopper 195a is provided on the back side of the foot pedal 195 to restrict the rotation of the foot pedal 195 by contacting the base plate 1a.
[0057]
Next, the operation of the above configuration will be described.
When the foot pedal 195 is stepped on from the state shown in FIG. 14 (B) to the state shown in FIG. 14 (A), the foot pedal 195 rotates with the brake petal shaft 196 and the petal operation plate 197 also rotates. When the petal operation plate 197 is released from the pressed state of the right operation plate 187b and the left operation plate 187a, the brake shoes 190a and 190b can freely rotate on the rotation shafts 186a and 186b.
Therefore, a spring 192 stretches between the bent portions of the arms 188a and 188b, and the ring-shaped brake shoes 190a and 190b press the universal wheel 3A from above, and become in a locked state.
[0058]
On the other hand, when the foot pedal 195 is stepped on in the opposite direction, the foot pedal 195 is rotated by the brake petal shaft 196 and the petal operation plate 197 is also rotated. Then, the petal operation plate 197 presses the left operation plate 187a and the right operation plate 187b, and the brake shoe is rotatable on the rotation shafts 186a and 186b integrally with the pressed left operation plate 187a and the right operation plate 187b. 190a and 190b overcome the tension of the spring 192, separate from the universal wheel 3A, and enter the unlocked state.
As described above, the brake operation of the universal wheel 3A can be easily performed by operating the foot pedal 195 using the ring-shaped brake shoes 190a and 190b for the universal wheel 3A.
[0059]
(Ninth embodiment)
The present embodiment provides a configuration in which even if one of the brake levers 202, 202 for the brake operation is operated, the same force as the other is equally distributed.
16 (A) is a front view of the bogie, FIG. 16 (B) is a side view of the bogie, FIG. 17 (A) is a partial enlarged view of the bogie, and a front view of the brake lever, and FIG. 17 (B) is a partial enlarged view of the bogie. FIG. 18 is a back view of the brake lever, and FIGS. 18A and 18B are views of the brake mechanism.
[0060]
Brake levers 202, 202 are attached to the left and right sides of the handle 201 of the cart. An upper plate 203 is fixed to a handle between the brake levers 202. An elongated hole 206 is formed in the upper plate 203, and a rotating shaft 205a is inserted into the elongated hole 206. The rotating shaft 205a is rotatable via a lock lever 205. In addition, a rectangular lock block 208 is attached to the rotation shaft 205a of the lock lever.
[0061]
A cover terminal 211 for fixing a covering cover 210a covering a wire 210 connected to the brake lever 202 is attached to an L-shaped operating body 209 which can be abutted on both sides of the lock block body 208 in a sandwiched state. .
Therefore, as will be described later in detail, when the lock block 208 is made to be able to reciprocate the operating body 209 by the lock lever 205 as shown in FIG. The operation body 209 reciprocates together with the wire 201, and the rotating shaft 205a (lock lever 205) reciprocates by the elongated hole 206. Therefore, even if one of the brake levers 202 is operated, The other brake lever 202 is also operated by equally distributing the force of the brake lever operation.
[0062]
The end of the wire is connected to a brake shoe 250 for locking or unlocking the wheel 3. A U-shaped attachment body 251 is attached to a lower portion of the base plate 1a, and a support 252 is attached to an end of the attachment body 251 at an application point of the brake shoe. The brake shoe 250 is a substantially U-shaped flat plate, and a spring 253 is inserted between the brake shoe 250 and the attachment body 251 to constantly bias the brake shoe 250 from the wheel 3 in the detaching direction. (Unlocked state).
Therefore, when the operating body 209 is allowed to reciprocate, when the brake lever 202 is gripped and the wire 210 is pulled, the brake shoe 250 is pressed by the support body 252 toward the wheel 3 to be in a locked state, but is released. Then, the brake shoe 250 separates from the wheel 3 and enters the unlocked state.
[0063]
Next, a description will be given of an operation of a configuration in which even if one of the brake levers 202, 202 of the brake operation is operated, the same force as that of the other brake lever can be equally distributed.
FIG. 17B shows a state in which the lock block body 208 is disabled by the lock lever 205 from reciprocating the operation body 209. Due to the state of the lock lever 205, the wire cannot be pulled by grasping the brake lever, and the brake shoe 250 is separated from the wheel 3 and is in an unlocked state. Therefore, this bogie is a bogie without brakes.
[0064]
Next, as shown in FIG. 17C, when the lock lever 205 is rotated, gaps 240 and 240 are generated between the operation bodies 209 by the lock block body 208, and the operation body 209 can reciprocate. At the same time, the rotating shaft 205a (the lock lever 205) can be reciprocated by the elongated hole 206.
Then, in this state, when one (or both) of the brake levers 202 is gripped and the wire 210 is pulled, the brake shoe 250 is pressed against the wheel 3 by the support 252 to be in a locked state (FIG. 18B )).
[0065]
At this time, when the wire 210 is pulled by gripping one of the brake levers 202, the rotation shaft 205a (the lock lever 205) also moves by the long hole 206, so that the operation is performed with the force equally distributed to one of the brake levers 202.
That is, this operation mechanism is the same as operating both brake levers, even if one of the brake levers is operated.
Accordingly, not only the left side is locked but also the right side is locked with the same force, which is preferable as a brake mechanism.
[0066]
(Tenth embodiment)
FIG. 19 (A) is a front view of a brake mechanism for stopping wheels 3 attached to a fixed caster, and FIG. 19 (B) is a side view. This brake mechanism is, for example, a bogie (shopping) shown in FIG. 12 (B). Dolly) etc. FIG. 19C is a perspective view of the brake shoe 175a, and FIG. 19D is a view of the stopper.
A fixed caster 171 is attached to a lower portion of the handle 151, and the wheel 3 rotates via a shaft 172.
[0067]
In addition, a brake shoe 175a that can be clamped on both sides of the wheel 3 when inserted from above the wheel 3 is attached to the front end of the wheel 3 at the lower end of the vertically movable gripping bar 162 via an auxiliary connecting tool 178a. . As shown in FIG. 19C, the brake shoe 175a is formed with a trapezoidal tapered portion 176 having a cutout portion narrowing from a lower portion to an upper portion.
Therefore, when the brake shoe 175a is lowered, the tapered portion 176 comes into contact with the wheel 3 sequentially at a narrow portion, and the both sides of the wheel 3 are sandwiched, and the brake is applied.
A brake shoe 175b is mounted on the rear side of the wheel 3 at a position symmetrical to the brake shoe 175a via a connecting body 177 connected to the grip bar 162 and an auxiliary connecting tool 178b.
[0068]
Next, the operation of the brake shoes 175a and 175b will be described. The brake shoes 175a and 175b are always in a downward direction, that is, in contact with both sides of the wheel 3 due to the weight of the grip bar 162.
Then, when the wheel 3 rotates clockwise, a force is applied to the wheel 3 to rotate the brake shoe 175a clockwise, so that the wheel 3 bites into the tapered portion 176 of the brake shoe 175a. Rotation is blocked.
On the other hand, when the wheel 3 rotates counterclockwise, a force is applied to the wheel 3 to rotate the brake shoe 175b clockwise, so that the wheel 3 bites into the tapered portion 176 of the brake shoe 175b, and the wheel 3 rotates clockwise. Is prevented from rotating.
As described above, the brake shoes 175a and 175b always maintain the brake state in which the rotation of the wheel 3 in the clockwise and counterclockwise directions is prevented.
On the other hand, in order to release the brake, the brake shoes 175a and 175b are separated from the wheels by raising the grip bar 162, and the vehicle can travel freely.
[0069]
As described above, the tapered portions 176 that sandwich the brake shoes 175a and 175b on both sides of the wheels 3 are formed, and the rotating wheels 3 are attached to the brake shoes 175a and 175b so that they can bite. The brake state can be maintained. When the brake shoes 175a and 175b are attached to the front and rear of the wheel, a brake state can be provided for the forward and backward movement of the wheel.
The brake shoes 175a and 175b have a simple configuration, and the rotating wheel 3 can be configured to bite into the tapered portion 176 of the brake shoes 175a and 175b by its own weight. A spring biasing downward is not necessary.
It should be noted that a brake shoe 175a may be provided to prevent the clockwise rotation of the wheel 3, but a brake shoe 175b may also be required to prevent the wheel 3 from rotating counterclockwise.
[0070]
FIG. 19D shows a stopper mechanism which keeps the unlocked state (the state where the brake is not applied) by disabling the vertically movable gripping bar 162.
As shown in FIG. 20 (C), a guide lever 502 whose both ends are rotatable is attached to an attachment plate 501 attached to the handle 151, and a stop body 503 is provided on the upper part of the grip bar 162, as shown in FIG. It is fixed. A stop support 505 that is rotatable and can be supported below the stop 503 is mounted on the mounting plate 501.
[0071]
Thus, as shown in FIG. 19D, when the stop support 505 is detached from the lower part of the stop 503, the grip bar 162 can be raised and lowered, and the locked state is always maintained, and the grip bar 162 is raised. It becomes unlocked.
However, when the stop support 505 is supported by the lower part of the stop 503, the grip bar 162 cannot be moved up and down, and the brake is always unlocked.
By providing the stop support 505 and the stop 503 in this manner, the unlocked state (the state in which the brake is not applied) can be easily maintained.
[0072]
FIG. 20 shows a brake mechanism using the brake shoes 175a and 175b forming the trapezoidal cutouts. The brake shoes 175a and 175b apply a brake or apply a brake to the wheel 3 in an inclined state. It is a configuration to cancel. Since this configuration is the same as that of the brake mechanism shown in FIG. 19, the description is omitted, but as described above, the brake shoes 175a and 175b may be mechanisms that act on the wheels 3 in an inclined manner.
[0073]
FIG. 21 shows a mechanism using the brake shoes 175a and 175b shown in FIG. 19. The brake shoes 175a and 175b are provided at the end of a vertically movable gripping bar 162 in front and behind the wheel 3. is there. That is, the brake shoe 175a is provided on the connected brake member 221 at the end of the grip bar 162, and the brake member 221 is extended toward the rear wheel, and the brake shoe 175b is attached to the extended end. Is provided.
A spring 220 is inserted between the brake member 221 and the upper part 222 of the caster, and the repulsive force of the spring 220 causes the brake shoes 175a and 175b to move downward from above the wheel 3 at all times. The pressed and braked locked state is maintained (FIG. 21A).
[0074]
However, when the vertically movable gripping bar 162 is lifted, the repulsive force of the spring 220 is overcome, and the brake shoes 175a and 175b are separated from the wheels and the brake is released (FIG. 21C).
As described above, by attaching the brake shoes 175a and 175b to the front and rear of the wheel 3, the brake shoe 175a and the brake shoe 175b bite into the wheel with respect to the forward and backward movements, thereby making the brake more complete. Can be.
[0075]
(Eleventh embodiment)
FIG. 22 shows a brake mechanism for the wheel 3, which has a structure in which brake shoes 190a, 190b sandwich both sides of the wheel 3, FIG. 22 (A) shows a brake state, and FIG. Indicates the status.
"U-shaped" brake shoes 190a, 190b capable of sandwiching both sides of the wheel 3 at the lower ends 191a, 191b are fixed to the holding members 192a, 192b at the lower portion, and have a circular cross section. , 192b are in contact with each other and are rotatable.
A spring 198 is connected to the upper portions of the brake shoes 190a and 190b, and the wire 199 is connected to a wire stopper 193 attached to the brake shoe 190a.
[0076]
Next, the operation of the brake mechanism will be described. As shown in FIG. 22 (A), when the wire 199 is not pulled, the brake shoe is supported by the repulsive force of the spring 198 with the holding members 192a and 192b as fulcrums. The lower ends 191a and 191b swing in the closing direction, are pinched from both sides of the wheel 3, and are in a braked state.
On the other hand, when the wire 199 is pulled, as shown in FIG. 22B, the spring 198 overcomes the repulsive force of the spring 198, and the spring 198 contracts, and the lower ends 191a and 191b of the brake shoes are mutually fixed with the holding members 192a and 192b as fulcrums. Rotating in the separating direction, the lower ends 191a and 191b of the brake shoes are separated from the wheels 3 and the brake is released.
In this way, it is possible to simply and always apply a brake via the spring 198 and pull the wire 199 so that the brake is not applied.
[0077]
(Twelfth embodiment)
23 and 24 show another brake mechanism of the truck, FIG. 23 (A) is a plan view of the truck with the base plate 1b removed, and FIGS. 23 (B) and (C) are X to X of (A). FIG. 24 is a view as viewed from the direction of the arrow, showing the operation of the foot pedal, and FIGS. 24 (A-1), (A-2), (B-1) and (B-2) are the views showing the operation of the brake.
A front wheel 401a and a rear wheel 401b are provided before and after the frame 450 of the bogie, and the brake mechanism uses the rear wheel 401b. The foot pedal 403 is rotatable at an angle of about 60 °, and a rotary shaft 405 is attached to the foot pedal 403 toward the rear wheel 401b of the bogie. An elliptical expansion cam 406 is attached to the tip of the rotation shaft 405. On both sides of the expansion cam 406, protrusions 407, 407 protruding from the brake transmission arm 410 are provided. It can move left and right on a support plate 408 attached to the frame 450.
[0078]
Further, a pivot bar 409 is suspended from the support plate 408, and a brake transmission arm 410 is rotatably attached to the pivot bar 409. Therefore, the brake transmission arm 410 moves while rotating with the rotation rod 409 along with the movement of the protrusion 407.
The brake transmission arm 410 is substantially shaped like a letter, and is maintained in a tensioned state by the spring 411 attached to the end so that the end becomes narrow. On the other hand, a bolt nut 428 for adjusting the strength of the brake shoe 425 is attached to the other end of the brake transmission arm 410.
[0079]
The brake shoe 425 is locked (brake) when it comes into contact with the rear wheel 401b, and is unlocked when it comes apart.
The brake shoe 425 is attached to the left surface side of a V-shaped brake plate 420 that is rotatable about a rotation shaft 421. The right front side of the brake plate 420 is in contact with the tip of a bolt nut 428 for adjusting the strength of the brake shoe 425, while the right back side of the brake plate 420 is fixed to the base plate 1b. A spring 422 is inserted between the spring 422 and the plate 429, and the brake plate 420 is always pressed against the adjustment bolt / nut 428, that is, the brake shoe 425 is in a direction of detaching from the rear wheel 401b.
[0080]
Next, the operation of the brake mechanism will be described. When the foot pedal 403 is depressed and the expansion cam 406 is set in a vertical state as shown in FIG. 23B, the left and right protrusions 407 being pulled by the spring 411 The distance between the (brake transmitting arm 410) and the projection 407 (brake transmitting arm 410) is the shortest.
Therefore, the brake transmission arm 410 rotates with the rotation rod 409, and the tip of the brake transmission arm 410 moves toward the rear wheel 401 b to press the adjusting bolt and nut 428 and overcome the repulsive force of the spring 422. Then, the brake plate 420 is rotated counterclockwise about the rotation shaft 421. As a result, the brake shoe 425 comes into contact with the rear wheel 401b to be in a locked state (brake is applied) (FIG. 24 (A-1, A-2)).
[0081]
On the other hand, when the stepping petal 403 is stepped on and the expansion cam 406 is inclined as shown in FIG. 23C, the left and right protrusions 407 (the brake transmission arm 410) and the protrusions 407 which are pulled by the spring 411. The interval between the (brake transmission arms 410) is the longest. Therefore, the brake transmission arm 410 is rotated by the rotation rod 409, and the tip of the brake transmission arm 410 moves in a direction away from the rear wheel 401b, and the pressing force of the adjusting bolt and nut 428 is reduced. Therefore, due to the repulsive force of the spring 422, the brake plate 420 rotates clockwise about the rotation shaft 421, and the brake shoe 425 separates from the rear wheel 401b to be in an unlocked state (no brake is applied) (FIG. 24). (B-1, B-2)).
As described above, by configuring the brake mechanism using the foot pedal 403, the locked and unlocked state can be easily achieved.
[0082]
As described above, the various brake mechanisms described above can be locked (in a state where the brake is applied) and unlocked (in a state where the brake is not applied) with a simple configuration. It is needless to say that the present invention is not limited to the configuration and can be appropriately combined and configured, and it is needless to say that the present invention can be applied to a bicycle and the like in addition to a truck.
[0083]
(Thirteenth embodiment)
This embodiment relates to the lock and unlock mechanism shown in FIGS. 25 and 26. FIG. 25 (A) is a front sectional view, FIG. 25 (B) is a right side view, and FIGS. () Is an enlarged view for explaining the operation.
The brake shoes 250 attached to the pair of wheels 3 are the same as those shown in FIGS. 16 and 18, and the brake is always released (unlocked) by the repulsive force of the spring 253. Therefore, the wire 210 covered with the coating 210b is always pulled in the direction of the wheel 3.
An inverted U-shaped handle 19 is provided upright on both side ends of the base plate 1a of the truck, and a thin plate-shaped base plate 301 is fixed to a lower portion on both sides of the handle 19, respectively. is there. Operation plates 303, 303 are attached to these substrates 301, 301 so as to be rotatable about rotation shafts 302, 302. An end 210a of the wire 210 is fixed to the right end of each of the operation plates 303, 303. On the left side, an inverted U-shaped operation body 305 is attached to the operation plate 303 and the operation plate 303. It is fixed.
[0084]
An upper support bar 310a and a lower support bar 310b are provided laterally at a predetermined interval on the handle 19 located above the substrate 301. The upper substrate 308 is attached to the upper support rod 310a and the lower support rod 310b, and the upper substrate 308 is provided with a pair of overhang bases 309. A substantially rectangular plate-shaped receiver 311 rotatable about a rotation shaft 310 is attached to the overhang bases 309 and 309. Note that a concave groove 312 capable of locking the operation body 305 is formed on the upper edge of the receiving body 311. The groove 312 is formed at a position where the receiver 311 does not move clockwise when the operation body 305 is mounted, even if the operation plate 303 rotates clockwise.
A threaded body 315 is inserted and fixed between the receivers 311 below the rotary shaft 310. Then, a torsion coil spring 318 is mounted between the upper substrate 308 and the through body 315, and the receiver 311 is constantly urged in a detaching direction from the upper substrate 308.
[0085]
Next, the operation of the above configuration will be described. First, the state shown in FIG. 26A is a state where the operating body 305 is detached from the groove 312. In this case, due to the repulsive force of the torsion coil spring 318, the receiver 311 moves in a direction of separating from the upper substrate 308. On the other hand, the wire 210 is pulled downward (toward the wheel 3) by the repulsive force of the spring 253, and the operation plate 303 rotates clockwise about the rotation shaft 302.
Therefore, the brake shoe 250 is in a state where the brake is released, as shown in FIG.
[0086]
On the other hand, when the operating body 305 is lifted and mounted in the groove 312, the wire 210 is pulled upward by overcoming the repulsive force of the spring 253, and a downward pulling force acts on the receiving body 311. And the state of FIG. 26B is maintained. Therefore, as shown in FIG. 18B, the spring 253 is contracted by the wire 210 pulled upward, and the brake shoe 250 comes into contact with the wheel 3 to be in a brake state (lock state).
As described above, the operating body 305 is mounted in the groove 312 formed in the receiving body 311 although it is normally in the unlocked state (the state where the brake is not applied) by the rotatable receiving body 311 and the operating body 305. This is a simple configuration in which the locked state is maintained, and the unlocked state is obtained by removing the locked state.
In addition, the above-mentioned state always corresponds to the unlocked state (the state in which the brake is not applied) via the wire 210, but may also correspond to the always-locked state (the state in which the brake is applied). .
[0087]
(14th embodiment)
This embodiment is a lock unlock mechanism shown in FIGS. 27A (locked state) and FIG. 27B (unlocked state).
FIGS. 27 (A) and 27 (B) are front views of the cart. Inverted U-shaped handles 19 are provided upright on both side ends of the board 1a of the cart.
The brake shoes 175a and 175b of the wheels are the same as those shown in FIG. 20, and a trapezoidal tapered portion 176 is formed. A torsion coil spring 326 is fitted between the brake shoes 175a and 175b and the support 325, and a force for rotating the brake shoes 175a and 175b clockwise in FIG. When the brake shoes 175a and 175b are lowered, the taper portion 176 abuts on the wheel 3 sequentially at a narrow portion, and the both sides of the wheel 3 are clamped, so that the brake is applied. The torsion coil spring 326 is not always necessary if the brake is sufficiently applied by the weight of the operation body 321 or the like.
[0088]
An inverted U-shaped operating body 321 is provided along the handles 19, 19 at both ends in connection with the brake shoes 175 a, 175 b. A base 322 is fixed in the middle of the handles 19, 19, and a link body 323 rotatable about a rotation shaft 322a is attached to the base 322. The operating body 321 is rotatably attached to a link body 323 via a lever 324 with a rotating shaft 324a. The base 322, the link body 323, and the operating body 321 constitute a link mechanism.
When the operating body 321 is lifted, the link body 323 is rotated via the lever 324, and the rotating shaft 324a is provided at a position on the left side of the rotating shaft 322a, so that the operating body 321 does not descend. To be locked.
[0089]
When the operation body 321 is lifted and rotated counterclockwise in FIG. 27, the link body 323 is rotated, and the rotation shaft 324a is moved to a position on the left side of the rotation shaft 322a. Lift. Therefore, the brake shoes 175a and 175b are separated from the wheel 3 to be in the brake release state (unlocked state), and the rotating shaft 324a is located on the left side of the rotating shaft 322a. Then, the operating body 321 is not lowered and is in the locked state. That is, the brake release state is maintained.
[0090]
Next, when the operation body 321 is slightly lifted and rotated clockwise in FIG. 27, the link body 323 is rotated clockwise on the rotation shaft 322a, and the locked state is released. Therefore, the operating body 321 descends, and the brake shoes 175a and 175b, the self-weight of the operating body 321 and the torsion coil spring 326 cause the trapezoidal tapered portion 176 of the brake shoe to sandwich both sides of the wheel 3 to apply the brake. (Locked state).
As described above, the brake can be locked and unlocked with a simple configuration using the operating body 321 and the link mechanism (consisting of the base 322, the link body 323, and the operating body 321) directly connected to the brake.
[0091]
(Fifteenth embodiment)
In the present embodiment, as shown in FIG. 28, a lock / unlock mechanism which is attached below the base plate 1a of the cart and operated by foot.
Below the base plate 1a, an L-shaped flat plate-shaped brake body 331 is provided, whose end is fixed to the back surface of the base plate 1a and which can abut on the wheel 3. The left side of the brake body 331 Constitutes the release petal 331a. On the right side of the center of the brake body 331, a support body 332 is suspended from the back surface of the base plate 1a, and a through-hole (not shown) is formed in the brake body 331. The brake body 331 is attached by inserting the support body 332 into a through hole (not shown), and a spring 333 biased from the back side of the brake body 331 to the back side of the base plate 1a is attached to the brake body 331. It is supported by being inserted into the support 332.
The brake body 331 has a rotating shaft 335 formed thereon, and a "L-shaped" stepping body 336 is attached to the rotating shaft 335, and between the stepping body 336 and the brake body 331. , A torsion coil spring (not shown) is attached thereto, and constantly urges the foot pedal 336 to rotate clockwise.
Further, a presser body 338 for pressing down the brake body 331 is attached to the foot step body 336, and the brake body 331 is moved up and down as the foot step body 336 moves up and down.
A stop 337 is provided on the back surface of the end of the base plate 1a to stop the rotating step body 336, and the end of the step body 336 contacts the back surface of the base plate 1a.
[0092]
Next, the operation of the above configuration will be described. When the footstep 336 is stepped downward, the footstep 336 rotates counterclockwise about the rotation shaft 335, and the brake body 331 is lowered (pressed) by the presser body 338. While stopping at the stop body 337. In addition, the end of the stepping member 336 contacts the back surface of the base plate 1a to lock the brake member 331.
Therefore, the brake body 331 contracts the spring 333 and descends, and the descending brake body 331 presses the wheel 3 to be in a brake state (lock state) (FIG. 28A).
On the other hand, when the release petal 331a is stepped on, the foot pedal 336 is detached from the back surface of the base plate 1a, and the foot pedal 336 is rotated by the torsion coil spring (not shown) mounted between the foot pedal 336 and the brake body 331. , The urging force for lowering (pressing) the brake body 331 by the pressing body 338 disappears, and the resilient force of the spring 333 raises the brake body 331 and separates from the wheel 3, so that the brake is released ( (Unlocked state) (FIG. 28B).
As described above, the lock and unlock state can be achieved by a simple mechanism constituted by the stepping body 336, the brake body 331, and the release petals 331a at the ends of the brake body 331.
[0093]
(Sixteenth embodiment)
This embodiment is described with reference to FIG. The brake mechanism according to the present embodiment switches between a locked state and an unlocked state via a link mechanism.
An inverted U-shaped handle 19 is provided upright at both ends of the bogie, and a rear wheel 3b is provided below the handle.
Further, flat brake shoes 175a and 175b, which press from above the rear wheel 3b to perform a braking action, are attached to the rear wheel 3b.
The brake shoes 175 a and 175 b are connected to an inverted U-shaped operating body 401 provided along the handle 19. A guide lever 402, which is not always necessary, is attached to the lower end of the operation body 401 so as to be rotatable between the handle 19 and the guide lever 402. An operation base 405 is mounted on the upper part of the operation body 401, and a handle base 403 is mounted on the handle 19. Further, a link lever 406 for rotatably connecting the operation base 405 and the handle base 403 is provided.
[0094]
Next, the operation of the above configuration will be described. When the operation body 401 is lifted up and pressed rightward in the state shown in FIG. 29A, the guide lever 402 rotates clockwise and the link lever 406 rotates clockwise. The position of the rotation axis of the link lever 406 on the operation base 405 is located on the right side of the position of the rotation axis of the link lever 406 on the handle base 403. Therefore, the link lever 406 does not receive a force for returning to the original state, and maintains the position where the brake shoes 175a and 175b are raised (FIG. 29A). Therefore, the brake maintains the released (unlocked) state.
[0095]
On the other hand, when the operating body 401 is lifted upward and rotated while pressing leftward in the state shown in FIG. 29A (FIG. 29B), the guide lever 402 rotates counterclockwise and When the link lever 406 is rotated counterclockwise, the position of the rotation axis of the link lever 406 on the operation base 405 is lower than the position of the rotation axis of the link lever 406 on the handle base 403, The brake shoes 175a and 175b descend to be pressed from above the rear wheel 3b (FIG. 29C).
The brake shoes 175a and 175b press the rear wheel 3b by their own weight and the own weight of the operating body 401 to perform a braking action. When the brake is not enough, a spring is used as an auxiliary force. .
As described above, this is a brake mechanism that locks and unlocks with a simple configuration of the link mechanism that uses the link lever 406 by raising and lowering the operating body 401.
The brake shoe attached to the lower end of the operating body 401 may be configured so that the brake is applied when the operating body 401 is lifted and the brake is released when the operating body 401 is lowered.
[0096]
(Seventeenth embodiment)
This embodiment is described with reference to FIG. FIG. 30A is a front view of the brake mechanism of the present embodiment, FIG. 30B is a plan view, and FIG. 30C is a view showing an unlocked state.
The brake mechanism according to the present embodiment is for locking and unlocking by the same operation as the first embodiment, but the left and right brake shoes 631a and 631b are symmetrical via the communication shaft bar 637. It is configured to be in a figure. Since the brake mechanism is symmetrical, only one of the brake mechanisms may be described.
[0097]
The pair of fixed bodies 620, 620 have the same structure as the mounting body 10 shown in FIG. 4, and are composed of a U-shaped base 621 (621a, 621b) and a base 622. Is provided with a mounting hole 623. The pair of fixed bodies 620 are attached to the base plate 1a of the bogie via the holes 623 by bolts and nuts 624 before and after the fixed wheel 3.
The U-shaped base 621 is provided with a rotating shaft 625 (625a, 625b). The rotating shaft 625 has a substantially L-shaped lever 630 (630a in plan view). , 630b) are rotatably mounted. A brake shoe 631 (631 a, 631 b) that can contact the front and rear of the wheel 3 and an L-shaped coupling body 636 are attached to the lever 630 with a bolt screw 632.
[0098]
The connecting bodies 636a and 636b mounted on the lever 630 are mounted symmetrically with respect to a point, and an elongated insertion hole 633 is formed at an end of the connecting bodies 636a and 636b. A communication shaft 637 is inserted into these insertion holes 633, and the left and right brake shoes 631a and 631b are configured to be symmetrical.
Operation shafts 640a and 640b are attached to upper ends of the levers 630a and 630b. The end of the wire 40 is fixed to the operation shaft 640a, and the wire 40 passes through an insertion hole (not shown) formed in the operation shaft 640b.
Note that a tension spring 650a is mounted between the operation shaft 640a and the base 621a, and the operation shaft 640a is urged counterclockwise about the rotation shaft 625a. A tension spring 650b is mounted between the bases 621b, and the operation shaft 640b is urged clockwise around the rotation shaft 625b, so that both the brake shoes 631a and 631b are in contact with the wheels 3. It is urged to rotate in the direction to achieve a locked state.
[0099]
The pair of levers 630a and 630b are interlocked by a communication shaft 637 and maintain a symmetrical state with each other. For example, even if one of the springs 650a stops working, the other spring 650b reduces the pulling force. Weaker but works the same. Therefore, the pair of brake shoes 631a and 631b is always urged to rotate in the direction in which the brake shoes 631a and 631b come into contact with the wheels 3 to achieve the locked state.
Next, when the wire 40 is pulled to release the locked state, the operation shaft 640a (the lever 630a) overcomes the pulling force of the spring 650a and is rotated clockwise around the rotation shaft 625a. On the other hand, the other lever 630b rotates counterclockwise via the communication shaft bar 637.
Therefore, the pair of brake shoes 631a and 631b are each turned in the direction in which the wheels 3 are separated from each other, and become in an unlocked state.
[0100]
As described above, this embodiment is locked and unlocked by the same operation as that of the first embodiment. However, the pair of brake shoes 631a and 631b are connected to the levers 630a and 630b, the coupling bodies 636a and 636b, and Since the brake shoes 631a and 631b, the levers 630a and 630b, and the connectors 636a and 636b are locked and unlocked in a symmetrical manner because they are alternately connected via the shaft bar 637. Note that the lever 630a (630b) and the connector 636a (636b) may be formed integrally.
[0101]
In the above-described embodiment, only the brake mechanism is illustrated and the case where the present invention is applied to a bogie is described. However, the present invention can be applied to a wheelchair and the like. In each of the embodiments, whether to always set the brake state or the brake release state may be selected and configured from the various brake mechanisms described above, and the structure in each of the embodiments may be appropriately changed. The brake mechanism may be configured in combination.
In the embodiment having a pair of brake shoes, the number of the brake shoes does not necessarily have to be a pair.
[0102]
【The invention's effect】
The brake mechanism attached to the vehicle according to any one of claims 1 to 8 and 10 has a simple structure including a brake shoe and a spring, and can be easily changed between a locked state and an unlocked state, so that the bogie is stopped on an inclined road or the like. Even so, safety can be ensured. Further, the brake shoe of claim 9 has a simple structure because the trapezoidal notch having the tapered portion cuts into the wheel and rotates into a locked state with the rotation of the wheel. Further, the brake mechanism attached to the vehicle according to claims 11 to 14 can be easily locked and unlocked.
[Brief description of the drawings]
FIG. 1A is a plan view of a cart, and FIG. 1B is a right side view.
FIG. 2A is a front view of a brake mechanism, and FIG. 2B is a side view.
3A is a locked state view of the brake mechanism viewed from the back side, and FIG. 3B is a side view of an unlocked state.
FIG. 4 is a diagram showing components of a brake mechanism.
5A is a plan view and FIG. 5B is a side sectional view of the lock and unlock mechanism.
6 (A) is a side view in a locked state, FIG. 6 (B) is a side view in an unlocked state, FIG. 6 (C) is a front view, and FIG. 6 (D) is a detailed view of a brake shoe. is there.
FIG. 7A is a locked state view of the brake mechanism viewed from the back side, and FIG. 7B is a side view of the locked state.
8A and 8B are diagrams showing a configuration of a wire, wherein FIG. 8A is a plan view, FIG. 8B is a side view, and FIG. 8C is a diagram showing a brake piece.
9A is a front view of a brake mechanism having another configuration, FIG. 9B is an enlarged view, and FIGS. 9C and 9D are views showing a locked state.
10A is a front view of a brake mechanism having another configuration, FIG. 10B is an enlarged view, and FIGS. 10C and 10D are views showing a locked state.
11 (A) to 11 (D) show a brake mechanism having another configuration, wherein FIG. 11 (A) shows an unlocked state, and FIGS. 11 (B) to 11 (D) show a locked state.
12 (A) is a side view, and FIG. 12 (B) is a front view, showing a brake mechanism of a universal wheel.
FIGS. 13A and 13B are diagrams showing a partially enlarged caster portion.
14A and 14B are diagrams showing a brake mechanism for a free wheel, in which FIG. 14A shows a front unlocked state, and FIG. 14B shows a front locked state.
FIG. 15 is a diagram showing a back surface in an unlocked state.
FIG. 16A is a front view of a trolley, and FIG. 16B is a side view of the trolley.
17A is a front view of a brake lever as an enlarged view of a part of the truck, and FIGS. 17B and 17C are partial enlarged views of the truck and a back view of the brake lever for explaining the operation.
FIGS. 18A and 18B are diagrams of a brake mechanism.
19 (A) is a front view of a brake mechanism for stopping wheels mounted on a fixed caster, FIG. 19 (B) is a side view, FIG. 19 (C) is a perspective view of a brake shoe, and FIG. Is a view of a stopper.
20 (A) is a front view of a brake mechanism for stopping wheels mounted on a fixed caster, FIG. 20 (B) is a side view, and FIG. 20 (C) is a partial view of a bogie.
21 (A) is a front view showing a locked state of a brake mechanism for stopping wheels mounted on a fixed caster, FIG. 21 (B) is a side view, and FIG. 21 (C) is a view showing an unlocked state. is there.
22A and 22B show another brake mechanism, wherein FIG. 22A shows a brake state, and FIG. 22B shows a runnable state.
23 (A) is a plan view of the bogie with the base plate removed, and FIGS. 23 (B) and 23 (C) are views taken along arrows X-X of FIG. 23 (A), showing the action of the foot pedal. FIG.
24 (A-1), (A-2), (B-1) and (B-2) are action diagrams of a brake.
FIG. 25 (A) is a front sectional view of a bogie, and FIG. 25 (B) is a right side view.
FIGS. 26A and 26B are enlarged views illustrating the operation.
27 (A) and 27 (B) are front views of a truck, FIG. 27 (A) is a view showing a locked state, and FIG. 27 (B) is a view showing an unlocked state.
28A and 28B are diagrams showing another lock / unlock mechanism of a brake, wherein FIG. 28A shows a locked state, and FIG. 28B shows an unlocked state.
FIGS. 29A and 29B show a lock / unlock mechanism having another configuration, in which FIG. 29A shows an unlocked state, FIG. 29B shows a state during operation, and FIG. 29C shows a locked state.
30A and 30B are lock unlock mechanisms having other configurations, where FIG. 30A is a front view showing a locked state, FIG. 30B is a plan view, and FIG. 30C is a view showing an unlocked state.
[Explanation of symbols]
1 body
1a Base plate
3 wheels
3b Rear wheel
10 Mounting body
20 spring
30 brake shoes
31 Shoe body
40 wires
50 Lock and unlock mechanism
70 base
71 Brake shoe
72 Brake base
73 spring

Claims (14)

A vehicle that can run with front wheels and fixed rear wheels attached to the back of the base plate,
A pair of brake shoes, which are rotatable and can be brought into contact with the front and rear of the fixed rear wheel, are mounted on a base mounted on a base plate, etc.
Attach wire pins to the ends of the pair of brake shoes,
A vehicle brake characterized in that a wire is connected with a spring inserted between these wire pins. A vehicle that can run with front wheels and fixed rear wheels attached to the back of the base plate,
A lever and a connecting body are rotatably provided on a base plate or the like, and a pair of brake shoes that can abut on front and rear of the fixed rear wheel are attached to the connecting body,
Always equipped with a tension spring via a connector so that the brake shoe can contact the wheel,
The connecting body and the connecting body are connected via a communication shaft rod,
A brake for a vehicle, wherein an end of a wire is fixed to an operation shaft attached to an upper end of the lever, and the wire is inserted through the other operation shaft. A vehicle that can run with front wheels and fixed rear wheels attached to the back of the base plate,
A base and a brake base rotatably mounted on a base plate etc. are provided rotatably,
Attached to the brake base is a shoe body that can abut on the shoulder of the rear wheel,
Insert a spring between the brake base and the base,
A brake for a vehicle, wherein a wire is connected to the brake base. A vehicle that can run with front wheels and fixed rear wheels attached to the back of the base plate,
On a base mounted on a base plate or the like, a spring is provided so that the shoe body can be brought into contact with the rear wheel side at all times before and after the fixed rear wheel,
Attach wire pins to the ends of a pair of brake shoes,
The wire 40 is inserted into the wire hole 42b formed in the wire pin 41b, and at the same time, is inserted through the inside of the cylindrical body 44 to fix the distal end of the wire 40 with the wire stopper 45,
The wire 40 inserted through the wire hole 42b is inserted through the wire hole 42a formed in the wire pin 41a, and after exiting the wire hole 42a, is inserted into a cover body 57 having a metal terminal 56. And the vehicle brakes. A vehicle that can run with front wheels and fixed rear wheels attached to the back of the base plate,
A spring 83 is inserted between a base attached to a base plate or the like and the lower bracket 82,
A brake for a vehicle, wherein inverted V-shaped brake pieces (85a, 85b) are supported by wires (40) under a lower metal fitting (82). A vehicle that can travel via wheels on the back of the base plate,
Wheels are rotatably mounted on casters mounted on a base plate, etc.
In the space above the casters, insert a brake shoe that forms a wave part that can contact the wheel,
Insert between the caster and the brake shoe, insert a spring that can press the wave part of the caster to the wheel,
A brake for a vehicle, wherein a wire for unlocking is attached to a brake shoe. A vehicle that can travel via a universal wheel attached to a universal caster on the back of the base plate,
A brake for a vehicle, comprising a brake shoe that can be contacted from above the universal wheel. A vehicle that can travel via wheels attached to the back of the base plate,
Providing a brake shoe that can contact the wheel,
While connecting the wire to this brake shoe, the wire is connected to the brake lever,
A lock block 208 is fixed to a rotation shaft 205a rotated by a lock lever 205, and the rotation shaft 205a is inserted into a long hole formed in the upper plate 203 fixed to a handle,
An L-shaped operating body 209 that can reciprocate with the wire is provided on both sides of the lock block body 208. A vehicle that can travel via wheels attached to the back surface of the base plate, and when inserted from above the wheels, provided brake shoes that can abut on both sides,
A brake for a vehicle, wherein the brake shoe has a tapered portion narrower from a lower portion to an upper portion. A vehicle that can travel via wheels attached to the back surface of the base plate, and provided with a pair of brake shoes that can abut on both sides of the wheels,
The lower portions of the pair of brake shoes are swingable via holding members 192a and 192b, and the upper portions are connected to a tension spring.
A vehicle brake, wherein a wire is connected to one of the brake shoes. An operation body 305 is attached to an operation plate 303 which is rotated about a rotation shaft 302 by a wire 210 which is always pulled downward.
A rotatable receiving body 311 is attached to the handle, and a groove 312 capable of supporting the operation body 305 is formed in the receiving body 311.
A brake for a vehicle, wherein the brake can be locked and unlocked when the operation body 305 is mounted on the groove 312 and when the operation body 305 is released. A brake of a vehicle in which the brake shoes 175a and 175b are brought into a brake state and a release state with respect to the wheels 3 by raising and lowering the operation body 321;
A brake for a vehicle, wherein a base 322 fixed to the handle 19 and the operating body 321 are connected by a link body 323. Under the base plate 1a, an end portion is fixed to the back surface of the base plate 1a, an L-shaped flat plate-shaped brake body 331 capable of contacting the wheel 3 is provided, and the end portion is a release petal 331a,
A support 332 is vertically provided on the back surface of the base plate 1a, and a spring for urging the brake body 331 toward the base plate is inserted into the support 332,
A rotatable stepping body 336 is attached to the brake body 331 via a rotating shaft 335 formed,
A torsion coil spring is mounted between the stepping body 336 and the brake body 331,
A brake for a vehicle, wherein a presser body 338 that presses the brake body 331 is attached to the foot step body 336. An operation body 401 is provided along the handle 19,
At the lower end of the operation body 401, brake shoes 175a and 175b capable of abutting on the rear wheel are attached,
An operation base 405 is mounted on the upper part of the operation body 401, and a handle base 403 is mounted on the handle 19, and these operation bases 405 and the handle base 403 are rotatably linked. A brake for a vehicle, comprising a lever (406).

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