JP3161354U - Telescopic tent roof - Google Patents

Abstract

An extendable tent roof that does not cause damage to an arm member regardless of whether it is exposed to wind, rain, or snow.
An eaves beam supported by a pair of arm mechanisms is connected to a front end edge of a tent member of a telescopic tent roof, and a winding mechanism is connected to a rear end edge. The extension arm mechanism has a first arm whose front end is connected to the eaves pier and a second arm whose front end is connected to the rear end of the first arm. A strip is wound around. One of the winding mechanism and the driving rope has a driving source and the other has an urging source. An urging force transmission control mechanism that allows or prevents transmission of the urging force from the urging source corresponding to the driving force of the driving source.
[Selection] Figure 1

Description

The present invention relates to a telescopic tent roof that is provided at the eaves of a store and the like, and is configured to be stretchable in order to block sunlight and rain.

Conventionally, the base end portion of the tent member is connected to the winding mechanism, the tip end portion is connected to the eaves frame, and the eaves frame can be foldable in order to support the eaves frame so as to be able to contact and separate from the building The thing which employ | adopted the structure formed by providing a pair of arm-shaped arm members is proposed (refer patent document 1).
If the telescopic tent roof with such a structure is provided, the tent roof can be extended only when necessary, such as when the sun is strong, and the sun can be blocked to achieve protection of displayed goods. , It is possible to plan the convenience of customers.

When the telescopic tent roof as described in Patent Document 1 is adopted and extended, the original function can be achieved without being affected by the wind.
However, it is extremely rare that the wind is not affected by the wind, and usually the wind is affected by the wind even though the intensity varies.
When the wind is affected, the entire stretchable tent roof receives wind, so the stretchable tent roof as a whole receives a considerable force, and the tent member receives the wind force. Thus, it will be pulled out larger than the original pulled out state.
In addition, it is rare that the tent member is pulled out evenly as a whole, and the tent member on one arm member side is usually pulled out larger than the tent member on the other arm member side, and the arm A large force is applied to the member.
In this case, only the upward force or the downward force is applied to the part connected to the eaves pier among the arm members, whereas the upward force is applied to the part connected to the building, Alternatively, not only a downward force but also a twisting force is applied.
As a result, the arm member (particularly, the portion of the arm member connected to the building) is easily damaged.
This inconvenience becomes particularly prominent when the telescopic tent roof is attached so as to extend obliquely upward, because it is easy to receive wind.

Considering this, it is conceivable to attach the telescopic tent roof so that it extends diagonally downward, but when affected by wind, rain, or snow, a relatively large downward force on the tent member or an upward comparison A large force will be applied, and the tent member will be pulled out larger than the original pulled-out state due to the force of wind, rain, and snow.
In addition, it is rare that the tent member is pulled out evenly as a whole, and the tent member on one arm member side is usually pulled out larger than the tent member on the other arm member side, and the arm A large force is applied to the member.
In this case, only the downward force or the upward force is applied to the part connected to the eaves pier among the arm members, whereas the downward force, to the part connected to the building, Alternatively, not only an upward force but also a twisting force is applied.
As a result, the arm member (particularly, the portion of the arm member connected to the building) is easily damaged.
And since the above inconvenience occurs even when a wind that is not particularly strong is blown, the telescopic tent roof cannot be used unless it is in a state close to no wind. End up. In other words, the conventional telescopic tent roof can only be used as a sun blocker when it is in a state of no wind.

JP 2005-188081 A

The problems to be solved by the present invention are as follows.
○ The first problem to be solved by the present invention The first problem to be solved by the present invention is that the arm member, even if it is affected by wind, rain, or snow. It is to provide a telescopic tent roof that is not easily damaged.

Means for solving the problems are the devices described in each claim of [Request for registration of utility model].
The terminology will be explained below in order to eliminate the doubts regarding the interpretation of the claims, specifications, drawings, etc. of the utility model registration request.
<Explanation of terms>
○ A tent member is a tent fabric that is waterproofed and used as a simple roof. It is preferable that not only the waterproof treatment but also the flameproof treatment.
The winding mechanism refers to a member used for winding the tent member, and enables the tent member to expand and contract (the portion of the tent member that is extended from the winding mechanism). A drum-like one is preferable. And the force for winding may be given by human power, but may be given by a spring, a motor or the like.
○ The eaves cross is a long member provided at the front end edge of the tent member, and the eaves cross can put the front end edge of the tent member in a tension state.
○ The telescopic arm mechanism is for connecting the eaves to the building so as to be close to and away from the building. The telescopic arm mechanism can support the tent member in a tensioned state regardless of the degree of expansion and contraction. .
The drive source is a device that actively applies a desired drive force as necessary, and examples thereof include a motor. Of course, a driving force may be actively given by manual operation.
The urging source always keeps the urging force applied in a predetermined direction, and examples thereof include a spring.
A rope is a string-like member that is wound to transmit power, and examples thereof include chains and wires.
A roller is a member on which a wire is wound, and includes a roller that is driven to rotate when the wire is wound, a member that simply guides the wire, and the like. Specifically, a sprocket, a chain wheel, a guide wheel, etc. can be illustrated.
○ The urging force transmission control mechanism is a mechanism that allows the urging force to be transmitted by the urging source in response to the driving source actively applying the driving force, and the driving source actively applies the driving force. In response to the absence, the transmission of the urging force by the urging source is prevented, and the free movement of the member to which the urging force is transmitted is prevented. Specific examples include a brake mechanism, a clutch mechanism, and a speed reduction mechanism with a significantly large reduction ratio, such as a worm gear mechanism.

The main reason why the present inventors noticed the importance of the problem to be solved by the present invention is that the greatest cause of the disadvantages of the prior art is the force in the twisting direction on the telescopic arm mechanism that expands and contracts the tent member. He did not realize that there was a need to eliminate acting.
The inventor has made various studies and searches for the possibility of using a telescopic tent roof without the possibility of damaging the telescopic arm mechanism even in the presence of wind, rain, or snow. The present invention has been completed.
Means for solving the problems are the inventions described in the claims described in the claims of the utility model registration of the present application, and specific means for solving them are as follows.
-First device (device described in claim 1)
A first device for solving the above problems (the device described in claim 1) is:
The leading edge of the tent member is connected to an eaves frame that is attached to the building and supported by a pair of telescopic arm mechanisms that operate in opposite directions within the same plane, and the trailing edge of the tent member serves as a winding mechanism. A telescopic tent roof that is connected,
The telescopic arm mechanism has a first arm whose front end is rotatably connected to the eaves pier, and a second arm whose rear end is rotatably connected to a fixed part of the building. The rear end portion and the tip end portion of the second arm are rotatably connected, and the length of the first arm and the length of the second arm are set to be equal to each other,
Having a drive cord wound around both ends of the second arm so as to extend the telescopic arm mechanism;
A winding mechanism, having a drive source that actively applies drive force to one of the drive cables;
A winding mechanism, and a biasing source that applies a biasing force to the other of the drive cables;
In response to the drive source actively applying the driving force, transmission of the urging force from the urging source is permitted, and in response to the drive source not actively applying the driving force, The telescopic tent roof has an urging force transmission control mechanism for preventing transmission of urging force from the motive force source.
-Second device (device described in claim 2)
A second device for solving the above problem (the device described in claim 2) is as follows.
The drive source is a device that actively applies a force in the extension direction to the telescopic arm mechanism via the drive rope,
2. The telescopic tent roof according to claim 1, wherein the urging source constantly applies a force in a winding direction to the winding mechanism via the driving rope.
-Third device (device described in claim 3)
A third device for solving the above problem (the device described in claim 3) is:
The drive source is a component that actively applies a force in the winding direction to the winding mechanism via the driving rope,
2. The telescopic tent roof according to claim 1, wherein the urging source constantly applies a force in the extending direction to the telescopic arm mechanism via the driving rope.

The telescopic tent roof according to the present invention is composed of the above-described characteristic constituent elements, and has the following effects specific to the present invention in accordance with the characteristic constituent elements.
Moreover, according to the telescopic tent roof comprised from the above characteristic structural requirements, the subject of this invention was able to be solved.
○ Effect of the first device According to the telescopic tent roof of the first device,
The leading edge of the tent member is connected to an eaves frame that is attached to the building and supported by a pair of telescopic arm mechanisms that operate in opposite directions within the same plane, and the trailing edge of the tent member serves as a winding mechanism. A telescopic tent roof that is connected,
The telescopic arm mechanism has a first arm whose front end is rotatably connected to the eaves pier, and a second arm whose rear end is rotatably connected to a fixed part of the building. The rear end portion and the tip end portion of the second arm are rotatably connected, and the length of the first arm and the length of the second arm are set to be equal to each other,
Having a drive cord wound around both ends of the second arm so as to extend the telescopic arm mechanism;
A winding mechanism, having a drive source that actively applies drive force to one of the drive cables;
A winding mechanism, and a biasing source that applies a biasing force to the other of the drive cables;
In response to the drive source actively applying the driving force, transmission of the urging force from the urging source is permitted, and in response to the drive source not actively applying the driving force, Due to the characteristic configuration requirement of having an urging force transmission control mechanism that prevents transmission of the urging force from the force source,
Even when the tent member is exposed to wind, rain, or snow, it is possible to prevent the tent member from being pulled out more than necessary. No torsional force is applied to the arm, and the arm member, particularly the second arm, is not easily damaged, and thus greatly reduces the restrictions on the weather conditions that can be used in the extended state. I was able to.
That is, the first problem to be solved by the present invention could be achieved, and a remarkable effect that could not be predicted by those skilled in the art could be achieved.
○ Effect of the second device According to the telescopic tent roof of the second device,
The drive source is a device that actively applies a force in the extension direction to the telescopic arm mechanism via the drive rope,
The biasing source has a characteristic component that a force in the winding direction is always applied to the winding mechanism via the driving cable,
Even when the tent member is exposed to wind, rain, or snow, it is possible to prevent the tent member from being pulled out more than necessary. No torsional force is applied to the arm, and the arm member, particularly the second arm, is not easily damaged, and thus greatly reduces the restrictions on the weather conditions that can be used in the extended state. I was able to.
That is, the first problem to be solved by the present invention could be achieved, and a remarkable effect that could not be predicted by those skilled in the art could be achieved.
○ Effect of the third device According to the telescopic tent roof of the third device,
The drive source is a component that actively applies a force in the winding direction to the winding mechanism via the driving rope,
The biasing source has a characteristic configuration requirement that a force in the extension direction is always applied to the telescopic arm mechanism via the driving rope,
Even when the tent member is exposed to wind, rain, or snow, it is possible to prevent the tent member from being pulled out more than necessary. No torsional force is applied to the arm, and the arm member, particularly the second arm, is not easily damaged, and thus greatly reduces the restrictions on the weather conditions that can be used in the extended state. I was able to.
That is, the first problem to be solved by the present invention could be achieved, and a remarkable effect that could not be predicted by those skilled in the art could be achieved.

It is a schematic plan view which shows one Embodiment of the expansion-contraction tent roof of this invention. It is a schematic side view which shows one Embodiment of the expansion-contraction tent roof of this invention. It is the schematic which shows the structure of a winding mechanism, (A) has shown the schematic plan view, (B) has shown the schematic back view, respectively.

Hereinafter, embodiments of the telescopic tent roof according to the present invention will be described in detail with reference to the accompanying drawings.
The telescopic tent roof of the first device is
The leading edge of the tent member is connected to an eaves frame that is attached to the building and supported by a pair of telescopic arm mechanisms that operate in opposite directions within the same plane, and the trailing edge of the tent member serves as a winding mechanism. A telescopic tent roof that is connected,
The telescopic arm mechanism has a first arm whose front end is rotatably connected to the eaves pier, and a second arm whose rear end is rotatably connected to a fixed part of the building. The rear end portion and the tip end portion of the second arm are rotatably connected, and the length of the first arm and the length of the second arm are set to be equal to each other,
Having a drive cord wound around both ends of the second arm so as to extend the telescopic arm mechanism;
A winding mechanism, having a drive source that actively applies drive force to one of the drive cables;
A winding mechanism, and a biasing source that applies a biasing force to the other of the drive cables;
In response to the drive source actively applying the driving force, transmission of the urging force from the urging source is permitted, and in response to the drive source not actively applying the driving force, An urging force transmission control mechanism for preventing the urging force from being transmitted from the urging source is provided.
The telescopic tent roof of the second device is
The drive source is a device that actively applies a force in the extension direction to the telescopic arm mechanism via the drive rope,
The urging source is characterized in that a force in the winding direction is always applied to the winding mechanism via the drive cable.
The telescopic tent roof of the third device is
The drive source is a component that actively applies a force in the winding direction to the winding mechanism via the driving rope,
The biasing source is characterized in that a force in the extending direction is always applied to the telescopic arm mechanism via the driving rope.

FIG. 1 is a schematic plan view showing an embodiment of a telescopic tent roof according to the present invention.
FIG. 2 is a schematic side view showing an embodiment of the telescopic tent roof according to the present invention.
FIGS. 3A and 3B are schematic views showing a configuration of a winding mechanism, in which FIG. 3A shows a schematic plan view and FIG. 3B shows a schematic rear view.
The telescopic tent roof according to the present invention has a winding mechanism M provided at a predetermined position of the building (for example, a wall portion above the entrance of the building), and is attached to the building and is opposite to each other in the same plane. A pair of telescopic arm mechanisms A that operate in the same manner, an eaves frame N supported by the distal ends of the pair of telescopic arm mechanisms A, and a leading edge connected to the eaves frame N and wound by a winding mechanism M. And a tent member T.
Although it is preferable to be attached to the girder member K supported in a horizontal state by the pillar member P of the building, it may be attached to other members above the girder member K. In addition, the winding mechanism M is a bearing member attached to a wall member above a girder member K supported in a horizontal state by a pillar member P of a building (it is conventionally known. It is preferably supported by a bearing member attached to the other position and member.
As shown in FIGS. 3A and 3B, the take-up mechanism M rotates in a state where it is connected to the base end edge of the tent member T, thereby taking up the tent member T. Mj, a shaft control mechanism (biasing force transmission control mechanism) Mjc capable of rotatably supporting the winding shaft Mj and preventing the winding shaft Mj from rotating, and a winding direction with respect to the winding shaft Mj A winding spring (biasing source) Ms that gives the rotational force of the winding, a drive chain Mc for transmitting the force of the winding spring Ms to the winding shaft Mj, and a winding transmitted by the driving chain Mc A take-up sprocket Mm that converts the pulling force of the spring Ms to a rotational force in the take-up direction, and a guide sprocket Mg that guides the drive chain Mc. The winding spring Ms is preferably a coil spring.
Further, one pair of guide sprockets Mg is provided corresponding to each take-up sprocket Mm, and each pair of guide sprockets Mg is rotatably provided on the same shaft. One of the pair of guide sprockets Mg faces each other, and the other of the pair of guide sprockets Mg faces each other. The drive chain Mc has one take-up sprocket Mm, one of the corresponding pair (one pair) of guide sprockets Mg, the other of the other pair of guide sprockets Mg, the other take-up sprocket Mm, and the other pair. One of the guide sprockets Mg is sequentially wound around the other of the pair of guide sprockets Mg, and is endlessly configured to return to the one take-up sprocket Mm again. By winding the drive chain Mc in this way, the force of the winding spring Ms can be applied to the winding sprocket Mm as a force in the winding direction.
Further, the outer diameter of the portion of the winding sprocket Mm around which the drive chain Mc is wound and the outer diameter of the winding shaft Mj can be set to arbitrary outer diameters. Therefore, for example, by setting the outer diameter of the winding shaft Mj to be sufficiently larger than the outer diameter of the portion of the winding sprocket Mm around which the drive chain Mc is wound, the length of the winding spring Ms is set. The length of the tent member T can be set to be sufficiently shorter than the length of expansion / contraction.
Further, the winding of the drive chain Mc around the take-up sprocket Mm may be achieved by winding the drive chain Mc only once, but it is achieved by winding the drive chain Mc any number of times two or more. Also good.
The telescopic arm mechanism A is formed by connecting the first arm A1 and the second arm A2 having the same length so as to be rotatable by an intermediate hinge, and the tip of the first arm A1 is connected to a predetermined position of the eaves frame N. The base end of the second arm A2 is rotatably connected to a predetermined position of the wall member of the building by the base hinge. The tent member T is contracted by folding both the telescopic arm mechanisms A so that the intermediate hinges of both the telescopic arm mechanisms A are close to each other.
The extendable arm mechanism extension mechanism D that extends the extendable arm mechanism A includes an extendable arm mechanism drive wire Dw and an extendable arm mechanism drive handle Dh.
The telescopic arm mechanism drive handle Dh winds up both telescopic arm mechanism drive wires Dw. A drive source such as a motor is connected to the telescopic arm mechanism drive handle Dh. However, the rotational force may be transmitted manually.
The telescopic arm mechanism drive wire Dw is connected at its proximal end to the telescopic arm mechanism drive handle Dh, wound around the outer side of the base hinge part and the inner side of the intermediate hinge part in this order, and the distal end part near the center of the first arm A1. It is connected to a predetermined position.
The shaft control mechanism Mjc allows the take-up shaft Mj to rotate in response to the telescopic arm mechanism drive handle Dh being actively rotated, and the telescopic arm mechanism drive handle Dh is actively rotated. In response to the absence, the rotation of the winding shaft Mj is prevented. Specifically, a brake mechanism controlled by a switch mechanism or the like, a clutch mechanism, a speed reduction mechanism with a significantly large reduction ratio, such as a worm gear mechanism, can be exemplified.
The operation of the telescopic tent roof having the above configuration is as follows.
(1) The state in which the telescopic tent roof is completely contracted In this state, since the telescopic arm mechanism drive handle Dh is not actively rotated, the shaft control mechanism Mjc rotates the winding shaft Mj. It is blocked.
(2) When the telescopic tent roof is extended: Both the telescopic arm mechanism drive wires Dw are wound up by actively rotating the telescopic arm mechanism drive handle Dh.
Following this operation, rotation of the winding shaft Mj is allowed by the shaft control mechanism Mj.
When the telescopic arm mechanism drive wire Dw is wound up, the telescopic arm mechanism moves the first arm A1 and the second arm A2 closer to one straight line due to being wound around the base hinge and the intermediate hinge in this order. A can be operated. That is, the telescopic arm mechanism A can be extended.
Therefore, the telescopic arm mechanism A can be extended according to the rotation amount of the telescopic arm mechanism drive handle Dh, and the tent member T can be extended.
(3) When the telescopic tent roof is extended When the telescopic tent roof has been extended, the telescopic arm mechanism drive handle Dh is not actively rotated. Therefore, the shaft control mechanism Mjc rotates the winding shaft Mj. Is blocked.
Therefore, the tent member T is in a stretched state.
When the telescopic tent roof receives wind in this state, the entire telescopic tent roof receives wind, but the shaft control mechanism Mjc is controlled to prevent the winding shaft Mj from rotating. It is possible to prevent the inconvenience that the tent member T is further pulled out by the wind. Of course, it is possible to prevent the inconvenience that the tent member T is pulled out larger on one side than the other side and becomes twisted.
As a result, only the upward force or the downward force acts on the first arm A1 and the second arm A2, and it is possible to prevent the twisting force from acting.
Even when the telescopic tent roof is affected by wind, rain, and snow, the entire telescopic tent roof is subjected to wind, rain, and snow, but the axis control mechanism Mjc is controlled to prevent the winding shaft Mj from rotating. Therefore, it is possible to prevent inconvenience that the tent member is further pulled out by the wind. Of course, it is possible to prevent the inconvenience that the tent member T is pulled out larger on one side than the other side and becomes twisted.
As a result, only the downward force or the upward force acts on the first arm A1 and the second arm A2, and it is possible to prevent the twisting force from acting.
Therefore, the strength of the entire telescopic tent roof can be improved, and restrictions on the weather conditions that can be used in the extended state can be greatly relaxed.
When the telescopic tent roof is subjected to wind and rain, as shown in FIG. 2, when the tent member T is extended obliquely upward, the base side of the tent member T (the side closer to the winding shaft Mj) ) Will accumulate rainwater. However, this inconvenience can be solved by making a hole in the portion of the tent member T where rainwater will accumulate and draining the rainwater. Of course, in this case, it is preferable to provide a member for transmitting rainwater, and scattering caused by the rainwater falling directly on the ground can be prevented in advance.
(4) When contracting the telescopic tent roof The telescopic arm mechanism drive wire Dw is fed out by rotating the telescopic arm mechanism drive handle Dh in the opposite direction to the case of extending the telescopic tent roof.
Following this operation, rotation of the winding shaft Mj is allowed by the shaft control mechanism Mjc.
When the extendable arm mechanism drive wire Dw is drawn out, the force for extending the extendable arm mechanism A is relaxed. At the same time, the tent member T is wound up to the above relaxed degree by the winding mechanism M in which the urging force by the winding spring Ms continues to act. Then, following the winding of the tent member T, the telescopic arm mechanism A is contracted to bring the eaves bridge N closer to the building.
As can be seen from the above description, the shaft control mechanism Mjc supports the winding shaft Mj rotatably only when the telescopic arm mechanism drive handle Dh is actively rotated to expand and contract the telescopic tent roof. Therefore, the tent member T can be pulled out and wound up smoothly.
In summary, when the telescopic arm mechanism drive handle Dh is not actively rotated, the shaft control mechanism Mjc prevents the winding shaft Mj from rotating. Even if it receives, generation | occurrence | production of the problem that the tent member T will be pulled out more than necessary (more than the pulling-out state before receiving the influence of a wind, a wind and rain, a wind and snow) can be prevented beforehand.
As a result, it is possible to prevent the force in the twisting direction from acting on each arm of the telescopic arm mechanism A, and it is possible to prevent the occurrence of inconvenience that the arm is easily damaged. That is, the strength of the telescopic tent roof can be improved. Therefore, the restrictions on the weather conditions that can be used in the extended state can be greatly relaxed.
In the above embodiment, the telescopic arm mechanism drive handle Dh is driven by a drive source such as a motor, the urging force of the take-up spring Ms is applied to the take-up shaft Mj, and the take-up force is taken up by the shaft control mechanism Mjc. A configuration is employed in which a state in which the rotation of the shaft Mj is allowed and a state in which the rotation of the winding shaft Mj is prevented are selected.
However, the winding shaft Mj is directly or indirectly driven by a drive source such as a motor, and a biasing force by a biasing source such as a spring is applied to the telescopic arm mechanism drive handle Dh. It is possible to adopt a configuration in which a state allowing the rotation of the telescopic arm mechanism drive handle Dh and a state preventing the rotation of the telescopic arm mechanism drive handle Dh can be adopted. It is possible to prevent a torsional force from acting on the arm, and to prevent the occurrence of a disadvantage that the arm is easily damaged. That is, the strength of the telescopic tent roof can be improved.

A telescopic arm mechanism A1 first arm A2 second arm D telescopic arm mechanism elongating mechanism Dh telescopic arm mechanism driving handle Dw telescopic arm mechanism driving wire K girder M winding mechanism Mc driving chain Mg guide sprocket Mj winding shaft Mjc axis control mechanism Mm Winding sprocket Ms Winding spring N Eaves T Tent member

Claims (3)

The leading edge of the tent member is connected to an eaves frame that is attached to the building and supported by a pair of telescopic arm mechanisms that operate in opposite directions within the same plane, and the trailing edge of the tent member serves as a winding mechanism. A telescopic tent roof that is connected,
The telescopic arm mechanism has a first arm whose front end is rotatably connected to the eaves pier, and a second arm whose rear end is rotatably connected to a fixed part of the building. The rear end portion and the tip end portion of the second arm are rotatably connected, and the length of the first arm and the length of the second arm are set to be equal to each other,
Having a drive cord wound around both ends of the second arm so as to extend the telescopic arm mechanism;
A winding mechanism, having a drive source that actively applies drive force to one of the drive cables;
A winding mechanism, and a biasing source that applies a biasing force to the other of the drive cables;
In response to the drive source actively applying the driving force, transmission of the urging force from the urging source is permitted, and in response to the drive source not actively applying the driving force, A telescopic tent roof characterized by having an urging force transmission control mechanism for preventing transmission of an urging force from a force source. The drive source is a device that actively applies a force in the extension direction to the telescopic arm mechanism via the drive rope,
2. The telescopic tent roof according to claim 1, wherein the urging source constantly applies a force in the winding direction to the winding mechanism via the driving rope. The drive source is a component that actively applies a force in the winding direction to the winding mechanism via the driving rope,
2. The telescopic tent roof according to claim 1, wherein the urging source constantly applies a force in the extending direction to the telescopic arm mechanism via the driving rope.

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