CN213499947U - Intensive concrete curing system - Google Patents

Abstract

The utility model relates to an intensive concrete curing system, including maintenance frame and actuating mechanism, a plurality of maintenance frame settings are on actuating mechanism to independently remove under actuating mechanism's effect. The beneficial effects are that: when the maintenance frame does not have relevant operation, maintenance frame equipartition densely on actuating mechanism, when needs are in operation on certain appointed maintenance frame, control actuating mechanism can move other maintenance frames as required according to appointed position and reduce the interval, thereby vacate the operation space of appointed maintenance frame and carry out relevant operation, after the operation is accomplished, no longer need the operation space, therefore control actuating mechanism can be with the increase of maintenance frame interval, thereby guarantee that the maintenance environment satisfies the relevant requirement of standard maintenance, in same maintenance room, the quantity of maintenance frame and the test block that can place greatly increased, and the work efficiency is improved, the potential safety hazard when having reduced artifical removal maintenance frame.

Description

Intensive concrete curing system

Technical Field

The utility model relates to a construction technical field, concretely relates to intensive concrete curing system.

Background

In engineering construction, a large number of structures are mainly formed by pouring concrete, the concrete is taken to be made into a standard test block for standard maintenance when the concrete is poured, and finally the strength of the concrete is determined through tests. Meanwhile, when the concrete mixing proportion test is carried out, the concrete is made into a standard test block for standard maintenance. Therefore, a large amount of concrete test blocks need to be cured in a standard curing room, and at present, the concrete test blocks are usually placed on a fixed curing frame for curing in the concrete standard curing room, but the space of the standard curing room is limited. Patent No. CN210210826U a detachable concrete test block maintenance support provides a portable maintenance frame of dismantling, nevertheless when depositing a great number of test blocks on the maintenance frame, the removal of maintenance frame is very inconvenient, has a lot of potential safety hazards simultaneously.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that an intensive concrete curing system is provided to overcome not enough among the above-mentioned prior art.

The utility model provides an above-mentioned technical problem's technical scheme as follows: the intensive concrete curing system comprises curing frames and a driving mechanism, wherein the curing frames are arranged on the driving mechanism and independently move under the action of the driving mechanism.

The utility model has the advantages that: when the maintenance frame does not have the relevant operation, maintenance frame equipartition densely on actuating mechanism, if interval 20cm, when needs are in operation on certain appointed maintenance frame, control actuating mechanism can move other maintenance frames according to appointed position as required and reduce the interval, if interval 5cm, thereby vacate the operation space of appointed maintenance frame and carry out relevant operation, after the operation is accomplished, no longer need the operation space, therefore control actuating mechanism can with maintenance frame interval increase, if interval 20cm, thereby guarantee that the maintenance environment satisfies the relevant requirement of standard maintenance, through adopting above-mentioned scheme, in same maintenance room, can greatly increased the quantity of maintenance frame and the test block that can place, work efficiency is improved, potential safety hazard when having reduced artifical removal maintenance frame.

On the basis of the technical scheme, the utility model discloses can also do following improvement.

Further, the driving mechanism comprises two rails and a plurality of wheel type moving assemblies, the two rails are arranged in parallel, and a plurality of maintenance frames are movably arranged on the rails; a wheel type moving assembly is arranged between each maintenance frame and the rail, and the maintenance frames can independently move on the two rails under the action of the wheel type moving assembly.

Further, wheeled removal subassembly includes driving motor and four guide pulleys, and four guide pulleys set up respectively in four corners of maintenance frame, four guide pulleys and two track clearance fits, and driving motor sets up in maintenance frame bottom to order about at least one guide pulley and rotate.

Adopt above-mentioned further beneficial effect to do: simple structure, good stability and independent regulation.

Further, still include power supply rail and current collector, power supply rail and track parallel arrangement all are equipped with the current collector with power supply rail electrical contact on every maintenance frame, and driving motor on every maintenance frame all is connected with the current collector electricity on this maintenance frame.

Adopt above-mentioned further beneficial effect to do: the cable laying can be cancelled, and the cable winding is prevented.

The maintenance frame is provided with a current collector, a wireless signal transceiver, an indoor environment monitoring device and a control terminal, wherein the current collector is electrically connected with the maintenance frame; the control terminal is in wireless connection with the wireless signal receiving and transmitting device.

Adopt above-mentioned further beneficial effect to do: the wireless signal receiving and transmitting device is added, the laying and winding problems of the signal wire are eliminated, and the indoor environment monitoring device can monitor the environmental information of the curing room so as to be adjusted in time.

Furthermore, the maintenance frame is formed by splicing or splicing a plurality of single-layer storage frame structures.

Furthermore, the single-layer storage rack structure is formed by assembling a plurality of single components through bolt connection.

The beneficial effects of the two steps are as follows: the maintenance frame can be assembled, the maintenance frame is composed of a plurality of layers of assembled structures, and the maintenance frame can be assembled into a corresponding height according to needs, so that space is saved.

Further, the driving motor is a stepping motor.

Adopt above-mentioned further beneficial effect to do: the maintenance racks can be adjusted to a proper interval by the characteristics of the stepping motor, so that the installation of the distance sensor can be omitted.

Further, still include distance sensor, all be equipped with distance sensor on every maintenance frame along the front and back of moving direction, distance sensor is connected with the wireless signal transceiver electricity on this maintenance frame.

Adopt above-mentioned further beneficial effect to do: the maintenance racks are provided with distance sensors for measuring the distance between the maintenance racks or the distance between the maintenance racks and the obstacle so as to be adjusted to a proper interval.

Drawings

Fig. 1 is the structure schematic diagram of the intensive concrete curing system of the utility model.

In the drawings, the components represented by the respective reference numerals are listed below:

1. maintenance frame, 2, track, 3, wheeled removal subassembly, 310, driving motor, 320, guide pulley, 4, power supply rail, 5, wireless signal transceiver, 6, indoor environment monitoring device, 7, distance sensor.

Detailed Description

The principles and features of the present invention are described below in conjunction with the following drawings, the examples given are only intended to illustrate the present invention and are not intended to limit the scope of the present invention.

Example 1

As shown in fig. 1, the intensive concrete curing system comprises curing frames 1 and a driving mechanism, wherein a plurality of curing frames 1 are arranged on the driving mechanism and independently move under the action of the driving mechanism.

Example 2

As shown in fig. 1, this embodiment is a further improvement on the basis of embodiment 1, and is specifically as follows:

the driving mechanism comprises two rails 2 and a plurality of wheel type moving assemblies 3, the two rails 2 are arranged in parallel, and a plurality of maintenance frames 1 are movably arranged on the rails 2; a wheel type moving assembly 3 is arranged between each maintenance frame 1 and the track 2, and the maintenance frames move on the two tracks 2 independently under the action of the wheel type moving assembly 3.

Example 3

As shown in fig. 1, this embodiment is a further improvement on the basis of embodiment 2, and is specifically as follows:

the wheel type moving assembly 3 comprises a driving motor 310 and four guide wheels 320, the four guide wheels 320 are respectively arranged at four corners of the maintenance frame 1, the four guide wheels 320 are movably matched with the two tracks 2, and each track 2 is movably matched with the two guide wheels 320; the driving motor 310 is disposed at the bottom of the curing frame 1, and the output shaft thereof is connected to the rotation center of at least one guide wheel 320, and normally, one guide wheel 320 is driven to rotate, and if the driving motor 310 is a dual output shaft motor, two guide wheels 320 can be driven to rotate at the same time, or the wheel moving assembly 3 includes two driving motors 310, and the two driving motors 310 respectively drive two guide wheels 320 which are not on the same track 2 to rotate.

Example 4

As shown in fig. 1, this embodiment is a further improvement on the basis of embodiment 3, and is specifically as follows:

intensive concrete maintenance system still includes power supply rail 4 and current collector, and power supply rail 4 and track 2 parallel arrangement all are equipped with the current collector with power supply rail 4 electrical contact on every maintenance frame 1, and driving motor 310 on every maintenance frame 1 all is connected with the current collector electricity on this maintenance frame 1, and whole structure is similar to the power supply form of track traffic.

Example 5

As shown in fig. 1, this embodiment is a further improvement on the basis of embodiment 4, and is specifically as follows:

the intensive concrete curing system also comprises a wireless signal transceiver 5, an indoor environment monitoring device 6 and a control terminal, wherein the indoor environment monitoring device 6 usually comprises a temperature sensor and a humidity sensor, each curing frame 1 is provided with the wireless signal transceiver 5 and the indoor environment monitoring device 6 which are electrically connected with a current collector on the curing frame 1, and the wireless signal transceiver 5 on each curing frame 1 is respectively electrically connected with the indoor environment monitoring device 6 and a driving motor 310 on the curing frame 1; the control terminal is wirelessly connected with the wireless signal transceiver 5, the control terminal can be a smart phone, a smart tablet or a computer, and the smart phone, the smart tablet or the computer can execute related operations through corresponding programs or micro-communication small programs after being connected with the local area network, or can check related conditions of a maintenance room after being connected with the internet, and the control terminal can also be a PLC (programmable logic controller).

Example 6

As shown in fig. 1, this embodiment is a further improvement performed on the basis of any one of embodiments 3 to 5, and specifically includes the following steps:

the driving motor 310 is a stepping motor.

Example 7

As shown in fig. 1, this embodiment is a further improvement performed on the basis of any one of embodiments 3 to 5, and specifically includes the following steps:

intensive concrete maintenance system still includes distance sensor 7, all is equipped with distance sensor 7 on every maintenance frame 1 along the front and back of moving direction, and distance sensor 7 is connected with wireless signal transceiver 5 electricity on this maintenance frame 1, and when driving motor 310 was step motor, can select not to install distance sensor 7 this moment.

Although embodiments of the present invention have been shown and described, it is understood that the above embodiments are exemplary and should not be construed as limiting the present invention, and that variations, modifications, substitutions and alterations can be made to the above embodiments by those of ordinary skill in the art without departing from the scope of the present invention.

Claims (9)

1. The intensive concrete curing system is characterized by comprising curing frames (1) and a driving mechanism, wherein the curing frames (1) are arranged on the driving mechanism and independently move under the action of the driving mechanism.

2. A dense concrete curing system according to claim 1, wherein said driving mechanism comprises two rails (2) and a plurality of wheel-type moving assemblies (3), said two rails (2) are arranged in parallel, and a plurality of said curing frames (1) are movably arranged on said rails (2); a wheel type moving assembly (3) is arranged between each maintenance frame (1) and the track (2), and the maintenance frames can independently move on the two tracks (2) under the action of the wheel type moving assembly (3).

3. A dense concrete curing system according to claim 2, wherein the wheel moving assembly (3) comprises a driving motor (310) and four guide wheels (320), the four guide wheels (320) are respectively arranged at four corners of the curing rack (1), the four guide wheels (320) are movably matched with the two rails (2), the driving motor (310) is arranged at the bottom of the curing rack (1) and drives at least one guide wheel (320) to rotate.

4. A dense concrete curing system according to claim 3, further comprising a power supply rail (4) and a current collector, wherein said power supply rail (4) is arranged in parallel with said track (2), each curing frame (1) is provided with a current collector in electrical contact with said power supply rail (4), and the driving motor (310) of each curing frame (1) is electrically connected with the current collector of the curing frame (1).

5. The intensive concrete curing system according to claim 4, further comprising a wireless signal transceiver (5), an indoor environment monitoring device (6) and a control terminal, wherein each curing frame (1) is provided with the wireless signal transceiver (5) and the indoor environment monitoring device (6) which are electrically connected with a current collector on the curing frame (1), and the wireless signal transceiver (5) on each curing frame (1) is electrically connected with the indoor environment monitoring device (6) and the driving motor (310) on the curing frame (1), respectively; the control terminal is in wireless connection with the wireless signal receiving and transmitting device (5).

6. A dense concrete curing system according to claim 3, wherein said curing rack (1) is formed by splicing or splicing a plurality of single-layer storage rack structures.

7. A intensive concrete curing system according to claim 6, wherein said single-deck storage rack structure is assembled from a plurality of single members by bolting.

8. A dense concrete curing system according to any one of claims 3-7, wherein said driving motor (310) is a stepping motor.

9. A dense concrete curing system according to any one of claims 3 to 7, further comprising distance sensors (7), wherein the distance sensors (7) are arranged on the front and back surfaces of each curing frame (1) along the moving direction, and the distance sensors (7) are electrically connected with the wireless signal transceiving devices (5) on the curing frames (1).

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